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How to Conduct Responsible Research: A Guide for Graduate Students

Alison l. antes.

1 Department of Medicine, Division of General Medical Sciences, Washington University School of Medicine, St. Louis, Missouri, 314-362-6006

Leonard B. Maggi, Jr.

2 Department of Medicine, Division of Molecular Oncology, Siteman Cancer Center, Washington University School of Medicine, St. Louis, Missouri, 314-362-4102

Researchers must conduct research responsibly for it to have an impact and to safeguard trust in science. Essential responsibilities of researchers include using rigorous, reproducible research methods, reporting findings in a trustworthy manner, and giving the researchers who contributed appropriate authorship credit. This “how-to” guide covers strategies and practices for doing reproducible research and being a responsible author. The article also covers how to utilize decision-making strategies when uncertain about the best way to proceed in a challenging situation. The advice focuses especially on graduate students but is appropriate for undergraduates and experienced researchers. The article begins with an overview of the responsible conduct of research, research misconduct, and ethical behavior in the scientific workplace. The takeaway message is that responsible conduct of research requires a thoughtful approach to doing research to ensure trustworthy results and conclusions and that researchers receive fair credit.

INTRODUCTION

Doing research is stimulating and fulfilling work. Scientists make discoveries to build knowledge and solve problems, and they work with other dedicated researchers. Research is a highly complex activity, so it takes years for beginning researchers to learn everything they need to know to do science well. Part of this large body of knowledge is learning how to do research responsibly. Our purpose in this article is to provide graduate students a guide for how to perform responsible research. Our advice is also relevant to undergraduate researchers and for principal investigators (PIs), postdocs, or other researchers who mentor beginning researchers and wish to share our advice.

We begin by introducing some fundamentals about the responsible conduct of research (RCR), research misconduct, and ethical behavior. We focus on how to do reproducible science and be a responsible author. We provide practical advice for these topics and present scenarios to practice thinking through challenges in research. Our article concludes with decision-making strategies for addressing complex problems.

What is the responsible conduct of research?

To be committed to RCR means upholding the highest standards of honesty, accuracy, efficiency, and objectivity ( Steneck, 2007 ). Each day, RCR requires engaging in research in a conscientious, intentional fashion that yields the best science possible ( “Research Integrity is Much More Than Misconduct,” 2019 ). We adopt a practical, “how-to” approach, discussing the behaviors and habits that yield responsible research. However, some background knowledge about RCR is helpful to frame our discussion.

The scientific community uses many terms to refer to ethical and responsible behavior in research: responsible conduct of research, research integrity, scientific integrity, and research ethics ( National Academies of Science, 2009 ; National Academies of Sciences Engineering and Medicine, 2017 ; Steneck, 2007 ). A helpful way to think about these concepts is “doing good science in a good manner” ( DuBois & Antes, 2018 ). This means that the way researchers do their work, from experimental procedures to data analysis and interpretation, research reporting, and so on, leads to trustworthy research findings and conclusions. It also includes respectful interactions among researchers both within research teams (e.g., between peers, mentors and trainees, and collaborators) and with researchers external to the team (e.g., peer reviewers). We expand on trainee-mentor relationships and interpersonal dynamics with labmates in a companion article ( Antes & Maggi, 2021 ). When research involves human or animal research subjects, RCR includes protecting the well-being of research subjects.

We do not cover all potential RCR topics but focus on what we consider fundamentals for graduate students. Common topics covered in texts and courses on RCR include the following: authorship and publication; collaboration; conflicts of interest; data management, sharing, and ownership; intellectual property; mentor and trainee responsibilities; peer review; protecting human subjects; protecting animal subjects; research misconduct; the role of researchers in society; and laboratory safety. A number of topics prominently discussed among the scientific community in recent years are also relevant to RCR. These include the reproducibility of research ( Baker, 2016 ; Barba, 2016 ; Winchester, 2018 ), diversity and inclusion in science ( Asplund & Welle, 2018 ; Hofstra et al., 2020 ; Meyers, Brown, Moneta-Koehler, & Chalkley, 2018 ; National Academies of Sciences Engineering and Medicine, 2018a ; Roper, 2019 ), harassment and bullying ( Else, 2018 ; National Academies of Sciences Engineering and Medicine, 2018b ; “ No Place for Bullies in Science,” 2018 ), healthy research work environments ( Norris, Dirnagl, Zigmond, Thompson-Peer, & Chow, 2018 ; “ Research Institutions Must Put the Health of Labs First,” 2018 ), and the mental health of graduate students ( Evans, Bira, Gastelum, Weiss, & Vanderford, 2018 ).

The National Institutes of Health (NIH) ( National Institutes of Health, 2009 ) and the National Science Foundation ( National Science Foundation, 2017 ) have formal policies indicating research trainees must receive education in RCR. Researchers are accountable to these funding agencies and the public which supports research through billions in tax dollars annually. The public stands to benefit from, or be harmed by, research. For example, the public may be harmed if medical treatments or social policies are based on untrustworthy research findings. Funding for research, participation in research, and utilization of the fruits of research all rely on public trust ( Resnik, 2011 ). Trustworthy findings are also essential for good stewardship of scarce resources ( Emanuel, Wendler, & Grady, 2000 ). Researchers are further accountable to their peers, colleagues, and scientists more broadly. Trust in the work of other researchers is essential for science to advance. Finally, researchers are accountable for complying with the rules and policies of their universities or research institutions, such as rules about laboratory safety, bullying and harassment, and the treatment of animal research subjects.

What is research misconduct?

When researchers intentionally misrepresent or manipulate their results, these cases of scientific fraud often make the news headlines ( Chappell, 2019 ; O’Connor, 2018 ; Park, 2012 ), and they can seriously undermine public trust in research. These cases also harm trust within the scientific community.

The U.S. defines research misconduct as fabrication, falsification, and plagiarism (FFP) ( Department of Health and Human Services, 2005 ). FFP violate the fundamental ethical principle of honesty. Fabrication is making up data, and falsification is manipulating or changing data or results so they are no longer truthful. Plagiarism is a form of dishonesty because it includes using someone’s words or ideas and portraying them as your own. When brought to light, misconduct involves lengthy investigations and serious consequences, such as ineligibility to receive federal research funding, loss of employment, paper retractions, and, for students, withdrawal of graduate degrees.

One aspect of responsible behavior includes addressing misconduct if you observe it. We suggest a guide titled “Responding to Research Wrongdoing: A User-Friendly Guide” that provides advice for thinking about your options if you think you have observed misconduct ( Keith-Spiegel, Sieber, & Koocher, 2010 ). Your university will have written policies and procedures for investigating allegations of misconduct. Making an allegation is very serious. As Keith-Spiegel et al.’s guide indicates, it is important to know the evidence that supports your claim, and what to expect in the process. We encourage, if possible, talking to the persons involved first. For example, one of us knew of a graduate student who reported to a journal editor their suspicion of falsified data in a manuscript. It turned out that the student was incorrect. Going above the PI directly to the editor ultimately led to the PI leaving the university, and the student had a difficult time finding a new lab to complete their degree. If the student had first spoken to the PI and lab members, they could have learned that their assumptions about the data in the paper were wrong. In turn, they could have avoided accusing the PI of a serious form of scientific misconduct—making up data—and harming everyone’s scientific career.

What shapes ethical behavior in the scientific workplace?

Responsible conduct of research and research misconduct are two sides of a continuum of behavior—RCR upholds the ideals of research and research misconduct violates them. Problematic practices that fall in the middle but are not defined formally as research misconduct have been labeled as detrimental research practices ( National Academies of Sciences Engineering and Medicine, 2017 ). Researchers conducting misleading statistical analyses or PIs providing inadequate supervision are examples of the latter. Research suggests that characteristics of individual researchers and research environments explain (un)ethical behavior in the scientific workplace ( Antes et al., 2007 ; Antes, English, Baldwin, & DuBois, 2018 ; Davis, Riske-Morris, & Diaz, 2007 ; DuBois et al., 2013 ).

These two influences on ethical behavior are helpful to keep in mind when thinking about your behavior. When people think about their ethical behavior, they think about their personal values and integrity and tend to overlook the influence of their environment. While “being a good person” and having the right intentions are essential to ethical behavior, the environment also has an influence. In addition, knowledge of standards for ethical research is important for ethical behavior, and graduate students new to research do not yet know everything they need to. They also have not fully refined their ethical decision-making skills for solving professional problems. We discuss strategies for ethical decision-making in the final section of this article ( McIntosh, Antes, & DuBois, 2020 ).

The research environment influences ethical behavior in a number of ways. For example, if a research group explicitly discusses high standards for research, people will be more likely to prioritize these ideals in their behavior ( Plemmons et al., 2020 ). A mentor who sets a good example is another important factor ( Anderson et al., 2007 ). Research labs must also provide individuals with adequate training, supervision and feedback, opportunities to discuss data, and the psychological safety to feel comfortable communicating about problems, including mistakes ( Antes, Kuykendall, & DuBois, 2019a , 2019b ). On the other hand, unfair research environments, inadequate supervision, poor communication, and severe stress and anxiety may undermine ethical decision-making and behavior; particularly when many of these factors exist together. Thus, (un)ethical behavior is a complex interplay of individual factors (e.g., personality, stress, decision-making skills) and the environment.

For graduate students, it is important to attend to what you are learning and how the environment around you might influence your behavior. You do not know what you do not know, and you necessarily rely on others to teach you responsible practices. So, it is important to be aware. Ultimately, you are accountable for your behavior. You cannot just say “I didn’t know.” Rather, just like you are curious about your scientific questions, maintain a curiosity about responsible behavior as a researcher. If you feel uncomfortable with something, pay attention to that feeling, speak to someone you trust, and seek out information about how to handle the situation. In what follows, we cover key tips for responsible behavior in the areas of reproducibility and authorship that we hope will help you as you begin.

HOW TO DO REPRODUCIBLE SCIENCE

The foremost responsibility of scientists is to ensure they conduct research in such a manner that the findings are trustworthy. Reproducibility is the ability to duplicate results ( Goodman, Fanelli, & Ioannidis, 2016 ). The scientific community has called for greater openness, transparency, and rigor as key remedies for lack of reproducibility ( Munafò et al., 2017 ). As a graduate student, essential to fostering reproducibility is the rigor of your approach to doing experiments and handling data. We discuss how to utilize research protocols, document experiments in a lab notebook, and handle data responsibly.

Utilize research protocols

1. learn and utilize the lab’s protocols.

Research protocols describe the step-by-step procedures for doing an experiment. They are critical for the quality and reproducibility of experiments. Lab members must learn and follow the lab’s protocols with the understanding that they may need to make adjustments based on the requirements of a specific experiment.

Also, it is important to distinguish between the experiment you are performing and analyzing the data from that experiment. For example, the experiment you want to perform might be to determine if loss of a gene blocks cell growth. Several protocols, each with pros and cons, will allow you to examine “cell growth.” Using the wrong experimental protocol can produce data that leads to muddled conclusions. In this example, the gene does block cell growth, but the experiment used to produce the data that you analyze to understand cell growth is wrong, thus giving a result that is a false negative.

When first joining a lab, it is essential to commit to learning the protocols necessary for your assigned research project. Researchers must ensure they are proficient in executing a protocol and can perform their experiments reliably. If you do not feel confident with a protocol, you should do practice runs if possible. Repetition is the best way to work through difficulties with protocols. Often it takes several attempts to work through the steps of a protocol before you will be comfortable performing it. Asking to watch another lab member perform the protocol is also helpful. Be sure to watch closely how steps are performed, as often there are minor steps taken that are not written down. Also, experienced lab members may do things as second nature and not think to explicitly mention them when working through the protocol. Ask questions of other lab members so that you can improve your knowledge and gain confidence with a protocol. It is better to ask a question than potentially ruin a valuable or hard-to-get sample.

Be cautious of differences in the standing protocols in the lab and how you actually perform the experiment. Even the most minor deviations can seriously impact the results and reproducibility of an experiment. As mentioned above, often there are minor things that are done that might not be listed in the protocol. Paying attention and asking questions are the best ways to learn, in addition to adding notes to the protocol if you find minor details are missing.

2. Develop your own protocols

Often you will find that a project requires a protocol that has not been performed in the lab. If performing a new experiment in the lab and no protocol exists, find a protocol and try it. Protocols can be obtained from many different sources. A great source is other labs on campus, as you can speak directly to the person who performs the experiment. There are many journal sources as well, such as Current Protocols, Nature Protocols, Nature Methods, and Cell STAR Methods . These methods journals provide the most detailed protocols for experiments often with troubleshooting tips. Scientific papers are the most common source of protocols. However, keep in mind that due to the common brevity of methods sections, they often omit crucial details or reference other papers that may not contain a complete description of the protocol.

3. Handle mistakes or problems promptly

At some point, everyone encounters problems with a protocol, or realizes they made a mistake. You should be prepared to handle this situation by being able to detail exactly how you performed the experiment. Did you skip a step? Shorten or lengthen a time point? Did you have to make a new buffer or borrow a labmate’s buffer? There are too many ways an experiment can go wrong to list here but being able to recount all the steps you performed in detail will help you work through the problem. Keep in mind that often the best way to understand how to perform an experiment is learning from when something goes wrong. This situation requires you to critically think through what was done and understand the steps taken. When everything works perfectly, it is easy to pay less attention to the details, which can lead to problems down the line.

It is up to you to be attentive and meticulous in the lab. Paying attention to the details may feel like a pain at first, or even seem overwhelming. Practice and repetition will help this focus on details become a natural part of your lab work. Ultimately, this skill will be essential to being a responsible scientist.

Document experiments in a lab notebook

1. recognize the importance of a lab notebook.

Maintaining detailed documentation in a lab notebook allows researchers to keep track of their experiments and generation of data. This detailed documentation helps you communicate about your research with others in the lab, and serves as a basis for preparing publications. It also provides a lasting record for the lab that exists beyond your time in the lab. After graduate students leave the lab, sometimes it is necessary to go back to the results of older experiments. A complete and detailed notebook is essential, or all of the time, effort, and resources are lost.

2. Learn the note-keeping practices in your lab

When you enter a new lab, it is important to understand how the lab keeps notebooks and the expectations for documentation. Being conscientious about documentation will make you a better scientist. In some labs, the PI might routinely examine your notebook, while in other labs you may be expected to maintain a notebook, but it may not be regularly viewed by others. It is tempting to become relaxed in documentation if you think your notebook may not be reviewed. Avoid this temptation; documentation of your ideas and process will improve your ability to think critically about research. Further, even if the PI or lab members do not physically view your notebook, you will need to communicate with them about your experiments. This documentation is necessary to communicate effectively about your work.

3. Organize your lab notebook

Different labs use different formats; some use electronic notebooks while others handwritten notebooks. The contents of a good notebook include the purpose of the experiment, the details of the experimental procedure, the data, and thoughts about the results. To effectively document your experiment, there are 5 critical questions that the information you record should be able to answer.

Why I am doing this experiment? (purpose)
What did I do to perform the experiment? (protocol)
What are the results of what I did? (data, graphs)
What do I think about the results?
What do I think are the next steps?

We also recommend a table of contents. It will make the information more useful to you and the lab in the future. The table of contents should list the title of the experiment, the date(s) it was performed, and the page numbers on which it is recorded. Also, make sure that you write clearly and provide a legend or explanation of any shorthand or non-standard abbreviation you use. Often labs will have a combination of written lab notebooks and electronic data. It is important to reference where electronic data are located that go with each experiment. The idea is to make it as easy as possible to understand what you did and where to find all the data (electronic and hard copy) that accompanies your experiment.

Keeping a lab notebook becomes easier with practice. It can be thought of almost like journaling about your experiment. Sometimes people think of it as just a place to paste their protocol and a graph or data. We strongly encourage you to include your thoughts about why you made the decisions you made when conducting the experiment and to document your thoughts about next steps.

4. Commit to doing it the right way

A common reason to become lax in documentation is feeling rushed for time. Although documentation takes time, it saves time in the long-run and fosters good science. Without good notes, you will waste time trying to recall precisely what you did, reproduce your findings, and remember what you thought would be important next steps. The lab notebook helps you think about your research critically and keep your thoughts together. It can also save you time later when writing up results for publication. Further, well-documented data will help you draft a cogent and rigorous dissertation.

Handle data responsibly

1. keep all data.

Data are the product of research. Data include raw data, processed data, analyzed data, figures, and tables. Many data today are electronic, but not all. Generating data requires a lot of time and resources and researchers must treat data with care. The first essential tip is to keep all data. Do not discard data just because the experiment did not turn out as expected. A lot of experiments do not turn out to yield publishable data, but the results are still important for informing next steps.

Always keep the original, raw data. That is, as you process and analyze data, always maintain an unprocessed version of the original data.

Universities and funding agencies have data retention policies. These policies specify the number of years beyond a grant that data must be kept. Some policies also indicate researchers need to retain original data that served as the basis for a publication for a certain number of years. Therefore, your data will be important well beyond your time in graduate school. Most labs require you to keep samples for reanalysis until a paper is published, then the analyzed data are enough. If you leave a lab before a paper is accepted for publication, you are responsible for ensuring your data and original samples are well documented for others to find and use.

2. Document all data

In addition to keeping all data, data must be well-organized and documented. This means that no matter the way you keep your data (e.g., electronic or in written lab notebooks), there is a clear guide—in your lab notebook, a binder, or on a lab hard drive—to finding the data for a particular experiment. For example, it must be clear which data produced a particular graph. Version control of data is also critical. Your documentation should include “metadata” (data about your data) that tracks versions of the data. For example, as you edit data for a table, you should save separate versions of the tables, name the files sequentially, and note the changes that were made to each version.

3. Backup your data

You should backup electronic data regularly. Ideally, your lab has a shared server or cloud storage to backup data. If you are supposed to put your data there, make sure you do it! When you leave the lab, it must be possible to find your data.

4. Perform data analysis honestly and competently

Inappropriate use of statistics is a major concern in the scientific community, as the results and conclusions will be misleading if done incorrectly ( DeMets, 1999 ). Some practices are clearly an abuse of statistics, while other inappropriate practices stem from lack of knowledge. For example, a practice called “p-hacking” describes when researchers “collect or select data or statistical analyses until nonsignificant results become significant” ( Head, Holman, Lanfear, Kahn, & Jennions, 2015 ). In addition to avoiding such misbehavior, it is essential to be proficient with statistics to ensure you do statistical procedures appropriately. Learning statistical procedures and analyzing data takes many years of practice, and your statistics courses may only cover the basics. You will need to know when to consult others for help. In addition to consulting members in your lab or your PI, your university may have statistical experts who can provide consultations.

5. Master pressure to obtain favored results

When you conduct an experiment, the results are the results. As a beginning researcher, it is important to be prepared to manage the frustration of experiments not turning out as expected. It is also important to manage the real or perceived pressure to produce favored results. Investigators can become wedded to a hypothesis, and they can have a difficult time accepting the results. Sometimes you may feel this pressure coming from yourself; for example, if you want to please your PI, or if you want to get results for a certain publication. It is important to always follow the data no matter where it leads.

If you do feel pressure, this situation can be uncomfortable and stressful. If you have been meticulous and followed the above recommendations, this can be one great safeguard. You will be better able to confidently communicate your results to the PI because of your detailed documentation, and you will be more confident in your procedures if the possibility of error is suggested. Typically, with enough evidence that the unexpected results are real, the PI will concede. We recommend seeking the support of friends or colleagues to vent and cope with stress. In the rare case that the PI does not relent, you could turn to an advisor outside the lab if you need advice about how to proceed. They can help you look at the data objectively and also help you think about the interpersonal aspects of navigating this situation.

6. Communicate about your data in the lab

A critical element of reproducible research is communication in the lab. Ideally, there are weekly or bi-weekly meetings to discuss data. You need to develop your communication skills for writing and speaking about data. Often you and your labmates will discuss experimental issues and results informally during the course of daily work. This is an excellent way to hone critical thinking and communication skills about data.

Scenario 1 – The Protocol is Not Working

At the beginning of a rotation during their first year, a graduate student is handed a lab notebook and a pen and is told to keep track of their work. There does not appear to be a specific format to follow. There are standard lab protocols that everyone follows, but minor tweaks to the protocols do not seem to be tracked from experiment to experiment in the standard lab protocol nor in other lab notebooks. After two weeks of trying to follow one of the standard lab protocols, the student still cannot get the experiment to work. The student has included the appropriate positive and negative controls which are failing, making the experiment uninterpretable. After asking others in the lab for help, the graduate student learns that no one currently in the lab has performed this particular experiment. The former lab member who had performed the experiment only lists the standard protocol in their lab notebook.

How should the graduate student start to solve the problem?

Speaking to the PI would be the next logical step. As a first-year student in a lab rotation, the PI should expect this type of situation and provide additional troubleshooting guidance. It is possible that the PI may want to see how the new graduate student thinks critically and handles adversity in the lab. Rather than giving an answer, the PI might ask the student to work through the problem. The PI should give guidance, but it may not be an immediate fix for the problem. If the PI’s suggestions fail to correct the problem, asking a labmate or the PI for the contact information of the former lab member who most recently performed the experiment would be a reasonable next step. The graduate student’s conversations with the PI and labmates in this situation will help them learn a lot about how the people in the lab interact.

Most of the answers for these types of problems will require you as a graduate student to take the initiative to answer. They will require your effort and ingenuity to talk to other lab members, other labs at the university, and even scour the literature for alternatives. While labs have standard protocols, there are multiple ways to do many experiments, and working out an alternative will teach you more than when everything works. Having to troubleshoot problems will result in better standard protocols in the lab and better science.

HOW TO BE A RESPONSIBLE AUTHOR

Researchers communicate their findings via peer-reviewed publications, and publications are important for advancing in a research career. Many graduate students will first author or co-author publications in graduate school. For good advice on how to write a research manuscript, consult the Current Protocols article “How to write a research manuscript” ( Frank, 2018 ). We focus on the issues of assigning authors and reporting your findings responsibly. First, we describe some important basics: journal impact factors, predatory journals, and peer review.

What are journal impact factors?

It is helpful to understand journal impact factors. There is criticism about an overemphasis on impact factors for evaluating the quality or importance of researchers’ work ( DePellegrin & Johnston, 2015 ), but they remain common for this purpose. Journal impact factors reflect the average number of times articles in a journal were cited in the last two years. Higher impact factors place journals at a higher rank. Approximately 2% of journals have an impact factor of 10 or higher. For example, Cell, Science, and Nature have impact factors of approximately 39, 42, and 43, respectively. Journals can be great journals but have lower impact factors; often this is because they focus on a smaller specialty field. For example, Journal of Immunology and Oncogene are respected journals, but their impact factors are about 4 and 7, respectively.

Research trainees often want to publish in journals with the highest possible impact factor because they expect this to be viewed favorably when applying to future positions. We encourage you to bear in mind that many different journals publish excellent science and focus on publishing where your work will reach the desired audience. Also, keep in mind that while a high impact factor can direct you to respectable, high-impact science, it does not guarantee that the science in the paper is good or even correct. You must critically evaluate all papers you read no matter the impact factor.

What are predatory journals?

Predatory journals have flourished over the past few years as publishing science has moved online. An international panel defined predatory journals as follows ( Grudniewicz et al., 2019 ):

Predatory journals and publishers are entities that prioritize self-interest at the expense of scholarship and are characterized by false or misleading information, deviation from best editorial and publication practices, a lack of transparency, and/or the use of aggressive and indiscriminate solicitation practices. (p. 211)

Often young researchers receive emails soliciting them to submit their work to a journal. There are typically small fees (around $99 US) requested but these fees will be much lower than open access fees of reputable journals (often around $2000 US). A warning sign of a predatory journal is outlandish promises, such as 24-hour peer review or immediate publication. You can find a list of predatory journals created by a postdoc in Europe at BeallsList.net ( “Beall’s List of Potential Predatory Journals and Publishers,” 2020 ).

What is peer review?

Peer reviewers are other scientists who have the expertise to evaluate a manuscript. Typically 2 or 3 reviewers evaluate a manuscript. First, an editor performs an initial screen of the manuscript to ensure its appropriateness for the journal and that it meets basic quality standards. At this stage, an editor can decide to reject the manuscript and not send it to review. Not sending a paper for peer review is common in the highest impact journals that receive more submissions per year than can be reviewed and published. For average-impact journals and specialty journals, typically your paper will be sent for peer review.

In general, peer review focuses on three aspects of a manuscript: research design and methods, validity of the data and conclusions, and significance. Peer reviewers assess the merit and rigor of the research design and methodology, and they evaluate the overall validity of the results, interpretations, and conclusions. Essentially, reviewers want to ensure that the data support the claims. Additionally, reviewers evaluate the overall significance, or contribution, of the findings, which involves the novelty of the research and the likelihood that the findings will advance the field. Significance standards vary between journals. Some journals are open to publishing findings that are incremental advancements in a field, while others want to publish only what they deem as major advancements. This feature can distinguish the highest impact journals which seek the most significant advancements and other journals that tend to consider a broader range of work as long as it is scientifically sound. It is important to keep in mind that determining at the stage of review and publication whether a paper is “high impact” is quite subjective. In reality, this can only really be determined in retrospect.

The key ethical issues in peer review are fairness, objectivity, and confidentiality ( Shamoo & Resnik, 2015 ). Peer reviewers are to evaluate the manuscript on its merits and not based on biases related to the authors or the science itself. If reviewers have a conflict of interest, this should be disclosed to the editor. Confidentiality of peer review means that the reviewers should keep private the information; they should not share the information with others or use it to their benefit. Reviewers can ultimately recommend that the manuscript is rejected, revised, and resubmitted (major or minor revisions), or accepted. The editor evaluates the reviewers’ feedback and makes a judgment about rejecting, accepting, or requesting a revision. Sometimes PIs will ask experienced graduate students to assist with peer reviewing a manuscript. This is a good learning opportunity. The PI should disclose to the editor that they included a trainee in preparing the review.

Assign authorship fairly

Authorship gives credit to the people who contributed to the research. This includes thinking of the ideas, designing and performing experiments, interpreting the results, and writing the paper. Two key questions regarding authorship include: 1 - Who will be an author? 2 - What will be the order in which authors are listed? These seem simple on the surface but can get quite complex.

1. Know authorship guidelines

Authorship guidelines published by journals, professional societies, and universities communicate key principles of authorship and standards for earning authorship. The core ethical principle of assigning authorship is fairness in who receives credit for the work. The people who contributed to the work should get credit for it. This seems simply enough, but determining authorship can (and often does) create conflict.

Many universities have authorship guidelines, and you should know the policies at your university. The International Committee of Medical Journal Editors (ICMJE) provides four criteria for determining who should be an author ( International Committee of Medical Journal Editors, 2020 ). These criteria indicate that an author should do all of the following: 1) make “substantial contributions” to the development of the idea or research design, or to acquiring, analyzing, or interpreting the data, 2) write the manuscript or revise it a substantive way, 3) give approval of the final manuscript (i.e., before it is submitted for review, and after it is revised, if necessary), and 4) agree to be responsible for any questions about the accuracy or integrity of the research.

Several types of authorship violate these guidelines and should be avoided. Guest authorship is when respected researchers are added out of appreciation, or to have the manuscript be perceived more favorably to get it published or increase its impact. Gift authorship is giving authorship to reward an individual, or as a favor. Ghost authorship is when someone made significant contributions to the paper but is not listed as an author. To increase transparency, some journals require authors to indicate how each individual contributed to the research and manuscript.

2. Apply the guidelines

Conflicts often arise from disagreements about how much people contributed to the research and whether those contributions merit authorship. The best approach is an open, honest, and ongoing discussion about authorship, which we discuss in #3 below. To have effective, informed conversations about authorship, you must understand how to apply the guidelines to your specific situation. The following is a simple rule of thumb that indicates there are three components of authorship. We do not list giving final approval of the manuscript and agreeing to be accountable, but we do consider these essentials of authorship.

Thinking – this means contributing to the ideas leading to the hypothesis of the work, designing experiments to address the hypothesis, and/or analyzing the results in the larger context of the literature in the field.
Doing – this means performing and analyzing the experiments.
Writing – this means editing a draft, or writing the entire paper. The first author often writes the entire first draft.

In our experience, a first author would typically do all three. They also usually coordinate the writing and editing process. Co-authors are typically very involved in at least two of the three, and are somewhat involved in the other. The PI, who oversees and contributes to all three, is often the last, or “senior author.” The “senior author” is typically the “corresponding author”—the person listed as the individual to contact about the paper. The other co-authors are listed between the first and senior author either alphabetically, or more commonly, in order from the largest to smallest contribution.

Problems in assigning authorship typically arise due to people’s interpretations of #1 (thinking) and #2 (doing)—what and how much each individual contributed to a project’s design, execution, and analysis. Different fields or PIs may have their own slight variations on these guidelines. The potential conflicts associated with assigning authorship lead to the most common recommendation for responsibly assigning authorship: discuss authorship expectations early and revisit them during the project.

3. Discuss authorship with your collaborators

Publications are important for career advancement, so you can see why people might be worried about fairness in assigning authorship. If the problem arises from a lack of a shared understanding about contributions to the research, the only way to clarify this is an open discussion. This discussion should ideally take place very early at the beginning of a project, and should be ongoing. Hopefully you work in a laboratory that makes these discussions a natural part of the research process; this makes it much easier to understand the expectations upfront.

We encourage you to speak up about your interest in making a contribution that would merit authorship, especially if you want to earn first authorship. Sometimes norms about authoring papers in a lab make it clear you are expected to first and co-author publications, but it is best to communicate your interest in earning authorship. If the project is not yours, but you wish to collaborate, you can inquire what you may be able to contribute that would merit authorship.

If it is not a norm in your lab to discuss authorship throughout the life of projects, then as a graduate student you may feel reluctant to speak up. You could initiate a conversation with a more senior graduate student, a postdoc, or your PI, depending on the dynamics in the group. You could ask generally about how the lab approaches assignment of authorship, but discussing a specific project and paper may be best. It may feel awkward to ask, but asking early is less uncomfortable than waiting until the end of the project. If the group is already drafting a manuscript and you are told that your contribution is insufficient for authorship, this situation is much more discouraging than if you had asked earlier about what is expected to earn authorship.

How to report findings responsibly

The most significant responsibility of authors is to present their research accurately and honestly. Deliberately presenting misleading information is clearly unethical, but there are significant judgment calls about how to present your research findings. For example, an author can mislead by overstating the conclusions given what the data support.

1. Commit to presenting your findings honestly

Any good scientific manuscript writer will tell you that you need to “tell a good story.” This means that your paper is organized and framed to draw the reader into the research and convince them of the importance of the findings. But, this story must be sound and justified by the data. Other authors are presenting their findings in the best, most “publishable” light, so it is a balancing act to be persuasive but also responsible in presenting your findings in a trustworthy manner. To present your findings honestly, you must be conscious of how you interpret your data and present your conclusions so that they are accurate and not overstated.

One misbehavior known as “HARKing,” Hypothesis After the Results are Known, occurs when hypotheses are created after seeing the results of an experiment, but they are presented as if they were defined prior to collecting the data ( Munafò et al., 2017 ). This practice should be avoided. HARKing may be driven, in part, by a concern in scientific publishing known as publication bias. This bias is a preference that reviewers, editors, and researchers have for papers describing positive findings instead of negative findings ( Carroll, Toumpakari, Johnson, & Betts, 2017 ). This preference can lead to manipulating one’s practices, such as by HARKing, so that positive findings can be reported.

It is important to note that in addition to avoiding misbehaviors such as HARKing, all researchers are susceptible to a number of more subtle traps in judgment. Even the most well-intentioned researcher may jump to conclusions, discount alternative explanations, or accept results that seem correct without further scrutiny ( Nuzzo, 2015 ). Therefore, researchers must not only commit to presenting their findings honestly but consider how they can counteract such traps by slowing down and increasing their skepticism towards their findings.

2. Provide an appropriate amount of detail

Providing enough detail in a manuscript can be a challenge with the word limits imposed by most journals. Therefore, you will need to determine what details to include and which to exclude, or potentially include in the supplemental materials. Methods sections can be long and are often the first to be shortened, but complete methods are important for others to evaluate the research and to repeat the methods in other studies. Even more significant is making decisions about what experimental data to include and potentially exclude from the manuscript. Researchers must determine what data is required to create a complete scientific story that supports the central hypothesis of the paper. On the other hand, it is not necessary or helpful to include so much data in the manuscript, or in supplemental material, that the central point of the paper is difficult to discern. It is a tricky balance.

3. Follow proper citation practices

Of course, responsible authorship requires avoiding plagiarism. Many researchers think that plagiarism is not a concern for them because they assume it is always done intentionally by “copying and pasting” someone else’s words and claiming them as your own. Sometimes poor writing practices, such as taking notes from references without distinguishing between direct quotes and paraphrased material, can lead to including material that is not quoted properly. More broadly, proper citation practices include accurately and completely referencing prior studies to provide appropriate context for your manuscript.

4. Attend to the other important details

The journal will require several pieces of additional information, such as disclosure of sources of funding and potential conflicts of interest. Typically, graduate students do not have relationships that constitute conflicts of interest, but a PI who is a co-author may. In submitting a manuscript, also make sure to acknowledge individuals not listed as authors but who contributed to the work.

5. Share data and promote transparency

Data sharing is a key facet of promoting transparency in science ( Nosek et al., 2015 ). It will be important to know the expectations of the journals in which you wish to publish. Many top journals now require data sharing; for example, sharing your data files in an online repository so others have access to the data for secondary use. Funding agencies like NIH also increasingly require data sharing. To further foster transparency and public trust in research, researchers must deposit their final peer-reviewed manuscripts that report on research funded by NIH to PubMed Central. PubMed makes biomedical and life science research publicly accessible in a free, online database.

Scenario 2 – Authors In Conflict

To prepare a manuscript for publication, a postdoc’s data is added to a graduate student’s thesis project. After working together to combine the data and write the paper, the postdoc requests co-first authorship on the paper. The graduate student balks at this request on the basis that it is their thesis project. In a weekly meeting with the lab’s PI to discuss the status of the paper, the graduate student states that they should divide the data between the authors as a way to prove that the graduate student should be the sole first author. The PI agrees to this attempt to quantify how much data each person contributed to the manuscript. All parties agree the writing and thinking were equally shared between them. After this assessment, the graduate student sees that the postdoc actually contributed more than half of the data presented in the paper. The graduate student and a second graduate student contributed the remaining data; this means the graduate student contributed much less than half of the data in the paper. However, the graduate student is still adamant that they must be the sole first author of the paper because it is their thesis project.

Is the graduate student correct in insisting that it is their project, so they are entitled to be the sole first author?

Co-first authorship became popular about 10 years ago as a way to acknowledge shared contributions to a paper in which authors worked together and contributed equally. If the postdoc contributed half of the data and worked with the graduate student to combine their interpretations and write the first draft of the paper, then the postdoc did make a substantial contribution. If the graduate student wrote much of the first draft of the paper, contributed significantly to the second half of data, and played a major role in the thesis concept and design, this is also a major contribution. We summarized authorship requirements as contributing to thinking, doing, and writing, and we noted that a first author usually contributes to all of these. The graduate student has met all 3 elements to claim first authorship. However, it appears that the postdoc has also met these 3 requirements. Thus, it is at least reasonable for the postdoc to ask about co-first authorship.

The best way to move forward is to discuss their perspectives openly. Both the graduate student and postdoc want first authorship on papers to advance their careers. The postdoc feels they contributed more to the overall concept and design than the graduate student is recognizing, and the postdoc did contribute half of the data. This is likely frustrating and upsetting for the postdoc. On the other hand, perhaps the postdoc is forgetting how much a thesis becomes like “your baby,” so to speak. The work is the graduate student’s thesis, so it is easy to see why the graduate student would feel a sense of ownership of it. Given this fact, it may be hard for the graduate student to accept the idea that they would share first-author recognition for the work. Yet, the graduate student should consider that the manuscript would not be possible without the postdoc’s contribution. Further, if the postdoc was truly being unreasonable, then the postdoc could make the case for sole first authorship based on contributing the most data to the paper, in addition to contributing ideas and writing the paper. The graduate student should consider that the postdoc may be suggesting co-first authorship in good faith.

As with any interpersonal conflict, clear communication is key. While it might be temporarily uncomfortable to voice their views and address this disagreement, it is critical to avoiding permanent damage to their working relationship. The pair should consider each other’s perspectives and potential alternatives. For example, if the graduate student is first author and the postdoc second, at a minimum they could include an author note in the manuscript that describes the contribution of each author. This would make it clear the scope of the postdoc’s contribution, if they decided not to go with co-first authorship. Also, the graduate student should consider their assumptions about co-first authorship. Maybe they assume it makes it appear they contributed less, but instead, perhaps co-first authorship highlights their collaborative approach to science. Collaboration is a desirable quality many (although arguably not all) research organizations look for when they are hiring.

They will also need to speak with others for advice. The pair should definitely speak with the PI who could provide input about how these cases have been handled in the past. Ultimately, if they cannot reach an agreement, the PI, who is likely to be the last or “senior” author, may make the final decision. They should also speak to the other graduate student who is an author.

If either individual is upset with the situation, they will want to discuss it when they have had time to cool down. This might mean taking a day before discussing, or speaking with someone outside of the lab for support. Ideally, all authors on this paper would have initiated this conversation earlier, and the standards in the lab for first authorship would be discussed routinely. Clear communication may have avoided the conflict.

HOW TO USE DECISION-MAKING STRATEGIES TO NAVIGATE CHALLENGES

We have provided advice on some specific challenges you might encounter in research. This final section covers our overarching recommendation that you adopt a set of ethical decision-making strategies. These strategies help researchers address challenges by helping them think through a problem and possible alternatives ( McIntosh et al., 2020 ). The strategies encourage you to gather information, examine possible outcomes, consider your assumptions, and address emotional reactions before acting. They are especially helpful when you are uncertain how to proceed, face a new problem, or when the consequences of a decision could negatively impact you or others. The strategies also help people be honest with themselves, such as when they are discounting important factors or have competing goals, by encouraging them to identify outside perspectives and test their motivations. You can remember the strategies using the acronym SMART .

1. S eek Help

Obtain input from others who can be objective and that you trust. They can assist you with assessing the situation, predicting possible outcomes, and identifying potential options. They can also provide you with support. Individuals to consult may be peers, other faculty, or people in your personal life. It is important that you trust the people you talk with, but it is also good when they challenge your perspective, or encourage you to think in a new way about a problem. Keep in mind that people such as program directors and university ombudsmen are often available for confidential, objective advice.

2. M anage Emotions

Consider your emotional reaction to the situation and how it might influence your assessment of the situation, and your potential decisions and actions. In particular, identify negative emotions, like frustration, anxiety, fear, and anger, as they particularly tend to diminish decision-making and the quality of interactions with others. Take time to address these emotions before acting, for example, by exercising, listening to music, or simply taking a day before responding.

3. A nticipate Consequences

Think about how the situation could turn out. This includes for you, for the research team, and anyone else involved. Consider the short, middle-term, and longer-term impacts of the problem and your potential approach to addressing the situation. Ideally, it is possible to identify win-win outcomes. Often, however, in tough professional situations, you may need to select the best option from among several that are not ideal.

4. R ecognize Rules and Context

Determine if any ethical principles, professional policies, or rules apply that might help guide your choices. For instance, if the problem involves an authorship dispute, consider the authorship guidelines that apply. Recognizing the context means considering the situational factors that could impact your options and how you proceed. For example, factors such as the reality that ultimately the PI may have the final decision about authorship.

5. T est Assumptions and Motives

Examine your beliefs about the situation and whether any of your thoughts may not be justified. This includes critically examining the personal motivations and goals that are driving your interpretation of the problem and thoughts about how to resolve it.

These strategies do not have to be engaged in order, and they are interrelated. For example, seeking help can help you manage emotions, test assumptions, and anticipate consequences. Go back to the scenarios and our advice throughout this article, and you will see many of our suggestions align with these strategies. Practice applying SMART strategies when you encounter a problem and they will become more natural.

Learning practices for responsible research will be the foundation for your success in graduate school and your career. We encourage you to be reflective and intentional as you learn and hope that our advice helps you along the way.

ACKNOWLEDGEMENTS

This work was supported by the National Human Genome Research Institute (Antes, K01HG008990) and the National Center for Advancing Translational Sciences (UL1 TR002345).

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2.1 Why is Research Important

Learning objectives.

By the end of this section, you will be able to:

Explain how scientific research addresses questions about behavior
Discuss how scientific research guides public policy
Appreciate how scientific research can be important in making personal decisions

Scientific research is a critical tool for successfully navigating our complex world. Without it, we would be forced to rely solely on intuition, other people’s authority, and blind luck. While many of us feel confident in our abilities to decipher and interact with the world around us, history is filled with examples of how very wrong we can be when we fail to recognize the need for evidence in supporting claims. At various times in history, we would have been certain that the sun revolved around a flat earth, that the earth’s continents did not move, and that mental illness was caused by possession (figure below). It is through systematic scientific research that we divest ourselves of our preconceived notions and superstitions and gain an objective understanding of ourselves and our world.

A skull has a large hole bored through the forehead.

Some of our ancestors, across the work and over the centuries, believed that trephination – the practice of making a hole in the skull, as shown here – allowed evil spirits to leave the body, thus curing mental illness and other diseases (credit” “taiproject/Flickr)

The goal of all scientists is to better understand the world around them. Psychologists focus their attention on understanding behavior, as well as the cognitive (mental) and physiological (body) processes that underlie behavior. In contrast to other methods that people use to understand the behavior of others, such as intuition and personal experience, the hallmark of scientific research is that there is evidence to support a claim. Scientific knowledge is empirical : It is grounded in objective, tangible evidence that can be observed time and time again, regardless of who is observing.

We can easily observe the behavior of others around us. For example, if someone is crying, we can observe that behavior. However, the reason for the behavior is more difficult to determine. Is the person crying due to being sad, in pain, or happy? Sometimes, asking about the underlying cognitions is as easy as asking the subject directly: “Why are you crying?” However, there are situations in which an individual is either uncomfortable or unwilling to answer the question honestly, or is incapable of answering. For example, infants would not be able to explain why they are crying. In other situations, it may be hard to identify exactly why you feel the way you do. Think about times when you suddenly feel annoyed after a long day. There may be a specific trigger for your annoyance (a loud noise), or you may be tired, hungry, stressed, or all of the above. Human behavior is often a complicated mix of a variety of factors. In such circumstances, the psychologist must be creative in finding ways to better understand behavior. This chapter explores how scientific knowledge is generated, and how important that knowledge is in forming decisions in our personal lives and in the public domain.

USE OF RESEARCH INFORMATION

In the meantime, we should strive to think critically about the information we encounter by exercising a degree of healthy skepticism. When someone makes a claim, we should examine the claim from a number of different perspectives: what is the expertise of the person making the claim, what might they gain if the claim is valid, does the claim seem justified given the evidence, and what do other researchers think of the claim? Science is always changing and new evidence is alwaus coming to light, thus this dash of skepticism should be applied to all research you interact with from now on. Yes, that includes the research presented in this textbook.

Evaluation of research findings can have widespread impact. Imagine that you have been elected as the governor of your state. One of your responsibilities is to manage the state budget and determine how to best spend your constituents’ tax dollars. As the new governor, you need to decide whether to continue funding the D.A.R.E. (Drug Abuse Resistance Education) program in public schools (figure below). This program typically involves police officers coming into the classroom to educate students about the dangers of becoming involved with alcohol and other drugs. According to the D.A.R.E. website (www.dare.org), this program has been very popular since its inception in 1983, and it is currently operating in 75% of school districts in the United States and in more than 40 countries worldwide. Sounds like an easy decision, right? However, on closer review, you discover that the vast majority of research into this program consistently suggests that participation has little, if any, effect on whether or not someone uses alcohol or other drugs (Clayton, Cattarello, & Johnstone, 1996; Ennett, Tobler, Ringwalt, & Flewelling, 1994; Lynam et al., 1999; Ringwalt, Ennett, & Holt, 1991). If you are committed to being a good steward of taxpayer money, will you fund this particular program, or will you try to find other programs that research has consistently demonstrated to be effective?

A D.A.R.E. poster reads “D.A.R.E. to resist drugs and violence.”

The D.A.R.E. program continues to be popular in schools around the world despite research suggesting that it is ineffective.

It is not just politicians who can benefit from using research in guiding their decisions. We all might look to research from time to time when making decisions in our lives. Imagine you just found out that a close friend has breast cancer or that one of your young relatives has recently been diagnosed with autism. In either case, you want to know which treatment options are most successful with the fewest side effects. How would you find that out? You would probably talk with a doctor or psychologist and personally review the research that has been done on various treatment options—always with a critical eye to ensure that you are as informed as possible.

In the end, research is what makes the difference between facts and opinions. Facts are observable realities, and opinions are personal judgments, conclusions, or attitudes that may or may not be accurate. In the scientific community, facts can be established only using evidence collected through empirical research.

THE PROCESS OF SCIENTIFIC RESEARCH

Two types of reasoning are used to make decisions within this model: Deductive and inductive. In deductive reasoning, ideas are tested against the empirical world. Think about a detective looking for clues and evidence to test their “hunch” about whodunit. In contrast, in inductive reasoning, empirical observations lead to new ideas. In other words, inductive reasoning involves gathering facts to create or refine a theory, rather than testing the theory by gathering facts (figure below). These processes are inseparable, like inhaling and exhaling, but different research approaches place different emphasis on the deductive and inductive aspects.

A diagram has a box at the top labeled “hypothesis or general premise” and a box at the bottom labeled “empirical observations.” On the left, an arrow labeled “inductive reasoning” goes from the bottom to top box. On the right, an arrow labeled “deductive reasoning” goes from the top to the bottom box.

Psychological research relies on both inductive and deductive reasoning.

In the scientific context, deductive reasoning begins with a generalization—one hypothesis—that is then used to reach logical conclusions about the real world. If the hypothesis is correct, then the logical conclusions reached through deductive reasoning should also be correct. A deductive reasoning argument might go something like this: All living things require energy to survive (this would be your hypothesis). Ducks are living things. Therefore, ducks require energy to survive (logical conclusion). In this example, the hypothesis is correct; therefore, the conclusion is correct as well. Sometimes, however, an incorrect hypothesis may lead to a logical but incorrect conclusion. Consider the famous example from Greek philosophy. A philosopher decided that human beings were “featherless bipeds”. Using deductive reasoning, all two-legged creatures without feathers must be human, right? Diogenes the Cynic (named because he was, well, a cynic) burst into the room with a freshly plucked chicken from the market and held it up exclaiming “Behold! I have brought you a man!”

Deductive reasoning starts with a generalization that is tested against real-world observations; however, inductive reasoning moves in the opposite direction. Inductive reasoning uses empirical observations to construct broad generalizations. Unlike deductive reasoning, conclusions drawn from inductive reasoning may or may not be correct, regardless of the observations on which they are based. For example, you might be a biologist attempting to classify animals into groups. You notice that quite a large portion of animals are furry and produce milk for their young (cats, dogs, squirrels, horses, hippos, etc). Therefore, you might conclude that all mammals (the name you have chosen for this grouping) have hair and produce milk. This seems like a pretty great hypothesis that you could test with deductive reasoning. You go out an look at a whole bunch of things and stumble on an exception: The coconut. Coconuts have hair and produce milk, but they don’t “fit” your idea of what a mammal is. So, using inductive reasoning given the new evidence, you adjust your theory again for an other round of data collection. Inductive and deductive reasoning work in tandem to help build and improve scientific theories over time.

We’ve stated that theories and hypotheses are ideas, but what sort of ideas are they, exactly? A theory is a well-developed set of ideas that propose an explanation for observed phenomena. Theories are repeatedly checked against the world, but they tend to be too complex to be tested all at once. Instead, researchers create hypotheses to test specific aspects of a theory.

A hypothesis is a testable prediction about how the world will behave if our theory is correct, and it is often worded as an if-then statement (e.g., if I study all night, I will get a passing grade on the test). The hypothesis is extremely important because it bridges the gap between the realm of ideas and the real world. As specific hypotheses are tested, theories are modified and refined to reflect and incorporate the result of these tests (figure below).

A diagram has four boxes: the top is labeled “theory,” the right is labeled “hypothesis,” the bottom is labeled “research,” and the left is labeled “observation.” Arrows flow in the direction from top to right to bottom to left and back to the top, clockwise. The top right arrow is labeled “use the hypothesis to form a theory,” the bottom right arrow is labeled “design a study to test the hypothesis,” the bottom left arrow is labeled “perform the research,” and the top left arrow is labeled “create or modify the theory.”

The scientific method of research includes proposing hypotheses, conducting research, and creating or modifying theories based on results.

To see how this process works, let’s consider a specific theory and a hypothesis that might be generated from that theory. As you’ll learn in a later chapter, the James-Lange theory of emotion asserts that emotional experience relies on the physiological arousal associated with the emotional state. If you walked out of your home and discovered a very aggressive snake waiting on your doorstep, your heart would begin to race and your stomach churn. According to the James-Lange theory, these physiological changes would result in your feeling of fear. A hypothesis that could be derived from this theory might be that a person who is unaware of the physiological arousal that the sight of the snake elicits will not feel fear.

A scientific hypothesis is also falsifiable, or capable of being shown to be incorrect. Recall from the introductory chapter that Sigmund Freud had lots of interesting ideas to explain various human behaviors (figure below). However, a major criticism of Freud’s theories is that many of his ideas are not falsifiable. The essential characteristic of Freud’s building blocks of personality, the id, ego, and superego, is that they are unconscious, and therefore people can’t observe them. Because they cannot be observed or tested in any way, it is impossible to say that they don’t exist, so they cannot be considered scientific theories. Despite this, Freud’s theories are widely taught in introductory psychology texts because of their historical significance for personality psychology and psychotherapy, and these remain the root of all modern forms of therapy.

(a)A photograph shows Freud holding a cigar. (b) The mind’s conscious and unconscious states are illustrated as an iceberg floating in water. Beneath the water’s surface in the “unconscious” area are the id, ego, and superego. The area just below the water’s surface is labeled “preconscious.” The area above the water’s surface is labeled “conscious.”

Many of the specifics of (a) Freud’s theories, such ad (b) his division on the mind into the id, ego, and superego, have fallen out of favor in recent decades because they are not falsifiable (i.e., cannot be verified through scientific investigation). In broader strokes, his views set the stage for much psychological thinking today, such as the idea that some psychological process occur at the level of the unconscious.

In contrast, the James-Lange theory does generate falsifiable hypotheses, such as the one described above. Some individuals who suffer significant injuries to their spinal columns are unable to feel the bodily changes that often accompany emotional experiences. Therefore, we could test the hypothesis by determining how emotional experiences differ between individuals who have the ability to detect these changes in their physiological arousal and those who do not. In fact, this research has been conducted and while the emotional experiences of people deprived of an awareness of their physiological arousal may be less intense, they still experience emotion (Chwalisz, Diener, & Gallagher, 1988).

Scientific research’s dependence on falsifiability allows for great confidence in the information that it produces. Typically, by the time information is accepted by the scientific community, it has been tested repeatedly.

Scientists are engaged in explaining and understanding how the world around them works, and they are able to do so by coming up with theories that generate hypotheses that are testable and falsifiable. Theories that stand up to their tests are retained and refined, while those that do not are discarded or modified. IHaving good information generated from research aids in making wise decisions both in public policy and in our personal lives.

Review Questions:

1. Scientific hypotheses are ________ and falsifiable.

a. observable

b. original

c. provable

d. testable

2. ________ are defined as observable realities.

a. behaviors

c. opinions

d. theories

3. Scientific knowledge is ________.

a. intuitive

b. empirical

c. permanent

d. subjective

4. A major criticism of Freud’s early theories involves the fact that his theories ________.

a. were too limited in scope

b. were too outrageous

c. were too broad

d. were not testable

Critical Thinking Questions:

1. In this section, the D.A.R.E. program was described as an incredibly popular program in schools across the United States despite the fact that research consistently suggests that this program is largely ineffective. How might one explain this discrepancy?

2. The scientific method is often described as self-correcting and cyclical. Briefly describe your understanding of the scientific method with regard to these concepts.

Personal Application Questions:

1. Healthcare professionals cite an enormous number of health problems related to obesity, and many people have an understandable desire to attain a healthy weight. There are many diet programs, services, and products on the market to aid those who wish to lose weight. If a close friend was considering purchasing or participating in one of these products, programs, or services, how would you make sure your friend was fully aware of the potential consequences of this decision? What sort of information would you want to review before making such an investment or lifestyle change yourself?

deductive reasoning

falsifiable

hypothesis: (plural

inductive reasoning

Answers to Exercises

Review Questions:

1. There is probably tremendous political pressure to appear to be hard on drugs. Therefore, even though D.A.R.E. might be ineffective, it is a well-known program with which voters are familiar.

2. This cyclical, self-correcting process is primarily a function of the empirical nature of science. Theories are generated as explanations of real-world phenomena. From theories, specific hypotheses are developed and tested. As a function of this testing, theories will be revisited and modified or refined to generate new hypotheses that are again tested. This cyclical process ultimately allows for more and more precise (and presumably accurate) information to be collected.

deductive reasoning: results are predicted based on a general premise

empirical: grounded in objective, tangible evidence that can be observed time and time again, regardless of who is observing

fact: objective and verifiable observation, established using evidence collected through empirical research

falsifiable: able to be disproven by experimental results

hypothesis: (plural: hypotheses) tentative and testable statement about the relationship between two or more variables

inductive reasoning: conclusions are drawn from observations

opinion: personal judgments, conclusions, or attitudes that may or may not be accurate

theory: well-developed set of ideas that propose an explanation for observed phenomena

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2.1 Why Is Research Important?

Learning objectives.

By the end of this section, you will be able to:

Explain how scientific research addresses questions about behavior
Discuss how scientific research guides public policy
Appreciate how scientific research can be important in making personal decisions

Scientific research is a critical tool for successfully navigating our complex world. Without it, we would be forced to rely solely on intuition, other people’s authority, and blind luck. While many of us feel confident in our abilities to decipher and interact with the world around us, history is filled with examples of how very wrong we can be when we fail to recognize the need for evidence in supporting claims. At various times in history, we would have been certain that the sun revolved around a flat earth, that the earth’s continents did not move, and that mental illness was caused by possession ( Figure 2.2 ). It is through systematic scientific research that we divest ourselves of our preconceived notions and superstitions and gain an objective understanding of ourselves and our world.

While behavior is observable, the mind is not. If someone is crying, we can see behavior. However, the reason for the behavior is more difficult to determine. Is the person crying due to being sad, in pain, or happy? Sometimes we can learn the reason for someone’s behavior by simply asking a question, like “Why are you crying?” However, there are situations in which an individual is either uncomfortable or unwilling to answer the question honestly, or is incapable of answering. For example, infants would not be able to explain why they are crying. In such circumstances, the psychologist must be creative in finding ways to better understand behavior. This chapter explores how scientific knowledge is generated, and how important that knowledge is in forming decisions in our personal lives and in the public domain.

Use of Research Information

Trying to determine which theories are and are not accepted by the scientific community can be difficult, especially in an area of research as broad as psychology. More than ever before, we have an incredible amount of information at our fingertips, and a simple internet search on any given research topic might result in a number of contradictory studies. In these cases, we are witnessing the scientific community going through the process of reaching a consensus, and it could be quite some time before a consensus emerges. For example, the explosion in our use of technology has led researchers to question whether this ultimately helps or hinders us. The use and implementation of technology in educational settings has become widespread over the last few decades. Researchers are coming to different conclusions regarding the use of technology. To illustrate this point, a study investigating a smartphone app targeting surgery residents (graduate students in surgery training) found that the use of this app can increase student engagement and raise test scores (Shaw & Tan, 2015). Conversely, another study found that the use of technology in undergraduate student populations had negative impacts on sleep, communication, and time management skills (Massimini & Peterson, 2009). Until sufficient amounts of research have been conducted, there will be no clear consensus on the effects that technology has on a student's acquisition of knowledge, study skills, and mental health.

In the meantime, we should strive to think critically about the information we encounter by exercising a degree of healthy skepticism. When someone makes a claim, we should examine the claim from a number of different perspectives: what is the expertise of the person making the claim, what might they gain if the claim is valid, does the claim seem justified given the evidence, and what do other researchers think of the claim? This is especially important when we consider how much information in advertising campaigns and on the internet claims to be based on “scientific evidence” when in actuality it is a belief or perspective of just a few individuals trying to sell a product or draw attention to their perspectives.

We should be informed consumers of the information made available to us because decisions based on this information have significant consequences. One such consequence can be seen in politics and public policy. Imagine that you have been elected as the governor of your state. One of your responsibilities is to manage the state budget and determine how to best spend your constituents’ tax dollars. As the new governor, you need to decide whether to continue funding early intervention programs. These programs are designed to help children who come from low-income backgrounds, have special needs, or face other disadvantages. These programs may involve providing a wide variety of services to maximize the children's development and position them for optimal levels of success in school and later in life (Blann, 2005). While such programs sound appealing, you would want to be sure that they also proved effective before investing additional money in these programs. Fortunately, psychologists and other scientists have conducted vast amounts of research on such programs and, in general, the programs are found to be effective (Neil & Christensen, 2009; Peters-Scheffer, Didden, Korzilius, & Sturmey, 2011). While not all programs are equally effective, and the short-term effects of many such programs are more pronounced, there is reason to believe that many of these programs produce long-term benefits for participants (Barnett, 2011). If you are committed to being a good steward of taxpayer money, you would want to look at research. Which programs are most effective? What characteristics of these programs make them effective? Which programs promote the best outcomes? After examining the research, you would be best equipped to make decisions about which programs to fund.

Link to Learning

Watch this video about early childhood program effectiveness to learn how scientists evaluate effectiveness and how best to invest money into programs that are most effective.

Ultimately, it is not just politicians who can benefit from using research in guiding their decisions. We all might look to research from time to time when making decisions in our lives. Imagine that your sister, Maria, expresses concern about her two-year-old child, Umberto. Umberto does not speak as much or as clearly as the other children in his daycare or others in the family. Umberto's pediatrician undertakes some screening and recommends an evaluation by a speech pathologist, but does not refer Maria to any other specialists. Maria is concerned that Umberto's speech delays are signs of a developmental disorder, but Umberto's pediatrician does not; she sees indications of differences in Umberto's jaw and facial muscles. Hearing this, you do some internet searches, but you are overwhelmed by the breadth of information and the wide array of sources. You see blog posts, top-ten lists, advertisements from healthcare providers, and recommendations from several advocacy organizations. Why are there so many sites? Which are based in research, and which are not?

NOTABLE RESEARCHERS

Psychological research has a long history involving important figures from diverse backgrounds. While the introductory chapter discussed several researchers who made significant contributions to the discipline, there are many more individuals who deserve attention in considering how psychology has advanced as a science through their work ( Figure 2.3 ). For instance, Margaret Floy Washburn (1871–1939) was the first woman to earn a PhD in psychology. Her research focused on animal behavior and cognition (Margaret Floy Washburn, PhD, n.d.). Mary Whiton Calkins (1863–1930) was a preeminent first-generation American psychologist who opposed the behaviorist movement, conducted significant research into memory, and established one of the earliest experimental psychology labs in the United States (Mary Whiton Calkins, n.d.).

Francis Sumner (1895–1954) was the first African American to receive a PhD in psychology in 1920. His dissertation focused on issues related to psychoanalysis. Sumner also had research interests in racial bias and educational justice. Sumner was one of the founders of Howard University’s department of psychology, and because of his accomplishments, he is sometimes referred to as the “Father of Black Psychology.” Thirteen years later, Inez Beverly Prosser (1895–1934) became the first African American woman to receive a PhD in psychology. Prosser’s research highlighted issues related to education in segregated versus integrated schools, and ultimately, her work was very influential in the hallmark Brown v. Board of Education Supreme Court ruling that segregation of public schools was unconstitutional (Ethnicity and Health in America Series: Featured Psychologists, n.d.).

Although the establishment of psychology’s scientific roots occurred first in Europe and the United States, it did not take much time until researchers from around the world began to establish their own laboratories and research programs. For example, some of the first experimental psychology laboratories in South America were founded by Horatio Piñero (1869–1919) at two institutions in Buenos Aires, Argentina (Godoy & Brussino, 2010). In India, Gunamudian David Boaz (1908–1965) and Narendra Nath Sen Gupta (1889–1944) established the first independent departments of psychology at the University of Madras and the University of Calcutta, respectively. These developments provided an opportunity for Indian researchers to make important contributions to the field (Gunamudian David Boaz, n.d.; Narendra Nath Sen Gupta, n.d.).

When the American Psychological Association (APA) was first founded in 1892, all of the members were White males (Women and Minorities in Psychology, n.d.). However, by 1905, Mary Whiton Calkins was elected as the first female president of the APA, and by 1946, nearly one-quarter of American psychologists were female. Psychology became a popular degree option for students enrolled in the nation’s historically Black higher education institutions, increasing the number of Black Americans who went on to become psychologists. Given demographic shifts occurring in the United States and increased access to higher educational opportunities among historically underrepresented populations, there is reason to hope that the diversity of the field will increasingly match the larger population, and that the research contributions made by the psychologists of the future will better serve people of all backgrounds (Women and Minorities in Psychology, n.d.).

The Process of Scientific Research

Scientific knowledge is advanced through a process known as the scientific method . Basically, ideas (in the form of theories and hypotheses) are tested against the real world (in the form of empirical observations), and those empirical observations lead to more ideas that are tested against the real world, and so on. In this sense, the scientific process is circular. The types of reasoning within the circle are called deductive and inductive. In deductive reasoning , ideas are tested in the real world; in inductive reasoning , real-world observations lead to new ideas ( Figure 2.4 ). These processes are inseparable, like inhaling and exhaling, but different research approaches place different emphasis on the deductive and inductive aspects.

In the scientific context, deductive reasoning begins with a generalization—one hypothesis—that is then used to reach logical conclusions about the real world. If the hypothesis is correct, then the logical conclusions reached through deductive reasoning should also be correct. A deductive reasoning argument might go something like this: All living things require energy to survive (this would be your hypothesis). Ducks are living things. Therefore, ducks require energy to survive (logical conclusion). In this example, the hypothesis is correct; therefore, the conclusion is correct as well. Sometimes, however, an incorrect hypothesis may lead to a logical but incorrect conclusion. Consider this argument: all ducks are born with the ability to see. Quackers is a duck. Therefore, Quackers was born with the ability to see. Scientists use deductive reasoning to empirically test their hypotheses. Returning to the example of the ducks, researchers might design a study to test the hypothesis that if all living things require energy to survive, then ducks will be found to require energy to survive.

Deductive reasoning starts with a generalization that is tested against real-world observations; however, inductive reasoning moves in the opposite direction. Inductive reasoning uses empirical observations to construct broad generalizations. Unlike deductive reasoning, conclusions drawn from inductive reasoning may or may not be correct, regardless of the observations on which they are based. For instance, you may notice that your favorite fruits—apples, bananas, and oranges—all grow on trees; therefore, you assume that all fruit must grow on trees. This would be an example of inductive reasoning, and, clearly, the existence of strawberries, blueberries, and kiwi demonstrate that this generalization is not correct despite it being based on a number of direct observations. Scientists use inductive reasoning to formulate theories, which in turn generate hypotheses that are tested with deductive reasoning. In the end, science involves both deductive and inductive processes.

For example, case studies, which you will read about in the next section, are heavily weighted on the side of empirical observations. Thus, case studies are closely associated with inductive processes as researchers gather massive amounts of observations and seek interesting patterns (new ideas) in the data. Experimental research, on the other hand, puts great emphasis on deductive reasoning.

We’ve stated that theories and hypotheses are ideas, but what sort of ideas are they, exactly? A theory is a well-developed set of ideas that propose an explanation for observed phenomena. Theories are repeatedly checked against the world, but they tend to be too complex to be tested all at once; instead, researchers create hypotheses to test specific aspects of a theory.

A hypothesis is a testable prediction about how the world will behave if our idea is correct, and it is often worded as an if-then statement (e.g., if I study all night, I will get a passing grade on the test). The hypothesis is extremely important because it bridges the gap between the realm of ideas and the real world. As specific hypotheses are tested, theories are modified and refined to reflect and incorporate the result of these tests Figure 2.5 .

A scientific hypothesis is also falsifiable , or capable of being shown to be incorrect. Recall from the introductory chapter that Sigmund Freud had lots of interesting ideas to explain various human behaviors ( Figure 2.6 ). However, a major criticism of Freud’s theories is that many of his ideas are not falsifiable; for example, it is impossible to imagine empirical observations that would disprove the existence of the id, the ego, and the superego—the three elements of personality described in Freud’s theories. Despite this, Freud’s theories are widely taught in introductory psychology texts because of their historical significance for personality psychology and psychotherapy, and these remain the root of all modern forms of therapy.

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What Is Research, and Why Do People Do It?

Open Access
First Online: 03 December 2022

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James Hiebert 6 ,
Jinfa Cai 7 ,
Stephen Hwang 7 ,
Anne K Morris 6 &
Charles Hohensee 6

Part of the book series: Research in Mathematics Education ((RME))

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Abstractspiepr Abs1

Every day people do research as they gather information to learn about something of interest. In the scientific world, however, research means something different than simply gathering information. Scientific research is characterized by its careful planning and observing, by its relentless efforts to understand and explain, and by its commitment to learn from everyone else seriously engaged in research. We call this kind of research scientific inquiry and define it as “formulating, testing, and revising hypotheses.” By “hypotheses” we do not mean the hypotheses you encounter in statistics courses. We mean predictions about what you expect to find and rationales for why you made these predictions. Throughout this and the remaining chapters we make clear that the process of scientific inquiry applies to all kinds of research studies and data, both qualitative and quantitative.

You have full access to this open access chapter, Download chapter PDF

Part I. What Is Research?

Have you ever studied something carefully because you wanted to know more about it? Maybe you wanted to know more about your grandmother’s life when she was younger so you asked her to tell you stories from her childhood, or maybe you wanted to know more about a fertilizer you were about to use in your garden so you read the ingredients on the package and looked them up online. According to the dictionary definition, you were doing research.

Recall your high school assignments asking you to “research” a topic. The assignment likely included consulting a variety of sources that discussed the topic, perhaps including some “original” sources. Often, the teacher referred to your product as a “research paper.”

Were you conducting research when you interviewed your grandmother or wrote high school papers reviewing a particular topic? Our view is that you were engaged in part of the research process, but only a small part. In this book, we reserve the word “research” for what it means in the scientific world, that is, for scientific research or, more pointedly, for scientific inquiry .

Exercise 1.1

Before you read any further, write a definition of what you think scientific inquiry is. Keep it short—Two to three sentences. You will periodically update this definition as you read this chapter and the remainder of the book.

This book is about scientific inquiry—what it is and how to do it. For starters, scientific inquiry is a process, a particular way of finding out about something that involves a number of phases. Each phase of the process constitutes one aspect of scientific inquiry. You are doing scientific inquiry as you engage in each phase, but you have not done scientific inquiry until you complete the full process. Each phase is necessary but not sufficient.

In this chapter, we set the stage by defining scientific inquiry—describing what it is and what it is not—and by discussing what it is good for and why people do it. The remaining chapters build directly on the ideas presented in this chapter.

A first thing to know is that scientific inquiry is not all or nothing. “Scientificness” is a continuum. Inquiries can be more scientific or less scientific. What makes an inquiry more scientific? You might be surprised there is no universally agreed upon answer to this question. None of the descriptors we know of are sufficient by themselves to define scientific inquiry. But all of them give you a way of thinking about some aspects of the process of scientific inquiry. Each one gives you different insights.

An image of the book's description with the words like research, science, and inquiry and what the word research meant in the scientific world.

Exercise 1.2

As you read about each descriptor below, think about what would make an inquiry more or less scientific. If you think a descriptor is important, use it to revise your definition of scientific inquiry.

Creating an Image of Scientific Inquiry

We will present three descriptors of scientific inquiry. Each provides a different perspective and emphasizes a different aspect of scientific inquiry. We will draw on all three descriptors to compose our definition of scientific inquiry.

Descriptor 1. Experience Carefully Planned in Advance

Sir Ronald Fisher, often called the father of modern statistical design, once referred to research as “experience carefully planned in advance” (1935, p. 8). He said that humans are always learning from experience, from interacting with the world around them. Usually, this learning is haphazard rather than the result of a deliberate process carried out over an extended period of time. Research, Fisher said, was learning from experience, but experience carefully planned in advance.

This phrase can be fully appreciated by looking at each word. The fact that scientific inquiry is based on experience means that it is based on interacting with the world. These interactions could be thought of as the stuff of scientific inquiry. In addition, it is not just any experience that counts. The experience must be carefully planned . The interactions with the world must be conducted with an explicit, describable purpose, and steps must be taken to make the intended learning as likely as possible. This planning is an integral part of scientific inquiry; it is not just a preparation phase. It is one of the things that distinguishes scientific inquiry from many everyday learning experiences. Finally, these steps must be taken beforehand and the purpose of the inquiry must be articulated in advance of the experience. Clearly, scientific inquiry does not happen by accident, by just stumbling into something. Stumbling into something unexpected and interesting can happen while engaged in scientific inquiry, but learning does not depend on it and serendipity does not make the inquiry scientific.

Descriptor 2. Observing Something and Trying to Explain Why It Is the Way It Is

When we were writing this chapter and googled “scientific inquiry,” the first entry was: “Scientific inquiry refers to the diverse ways in which scientists study the natural world and propose explanations based on the evidence derived from their work.” The emphasis is on studying, or observing, and then explaining . This descriptor takes the image of scientific inquiry beyond carefully planned experience and includes explaining what was experienced.

According to the Merriam-Webster dictionary, “explain” means “(a) to make known, (b) to make plain or understandable, (c) to give the reason or cause of, and (d) to show the logical development or relations of” (Merriam-Webster, n.d. ). We will use all these definitions. Taken together, they suggest that to explain an observation means to understand it by finding reasons (or causes) for why it is as it is. In this sense of scientific inquiry, the following are synonyms: explaining why, understanding why, and reasoning about causes and effects. Our image of scientific inquiry now includes planning, observing, and explaining why.

An image represents the observation required in the scientific inquiry including planning and explaining.

We need to add a final note about this descriptor. We have phrased it in a way that suggests “observing something” means you are observing something in real time—observing the way things are or the way things are changing. This is often true. But, observing could mean observing data that already have been collected, maybe by someone else making the original observations (e.g., secondary analysis of NAEP data or analysis of existing video recordings of classroom instruction). We will address secondary analyses more fully in Chap. 4 . For now, what is important is that the process requires explaining why the data look like they do.

We must note that for us, the term “data” is not limited to numerical or quantitative data such as test scores. Data can also take many nonquantitative forms, including written survey responses, interview transcripts, journal entries, video recordings of students, teachers, and classrooms, text messages, and so forth.

An image represents the data explanation as it is not limited and takes numerous non-quantitative forms including an interview, journal entries, etc.

Exercise 1.3

What are the implications of the statement that just “observing” is not enough to count as scientific inquiry? Does this mean that a detailed description of a phenomenon is not scientific inquiry?

Find sources that define research in education that differ with our position, that say description alone, without explanation, counts as scientific research. Identify the precise points where the opinions differ. What are the best arguments for each of the positions? Which do you prefer? Why?

Descriptor 3. Updating Everyone’s Thinking in Response to More and Better Information

This descriptor focuses on a third aspect of scientific inquiry: updating and advancing the field’s understanding of phenomena that are investigated. This descriptor foregrounds a powerful characteristic of scientific inquiry: the reliability (or trustworthiness) of what is learned and the ultimate inevitability of this learning to advance human understanding of phenomena. Humans might choose not to learn from scientific inquiry, but history suggests that scientific inquiry always has the potential to advance understanding and that, eventually, humans take advantage of these new understandings.

Before exploring these bold claims a bit further, note that this descriptor uses “information” in the same way the previous two descriptors used “experience” and “observations.” These are the stuff of scientific inquiry and we will use them often, sometimes interchangeably. Frequently, we will use the term “data” to stand for all these terms.

An overriding goal of scientific inquiry is for everyone to learn from what one scientist does. Much of this book is about the methods you need to use so others have faith in what you report and can learn the same things you learned. This aspect of scientific inquiry has many implications.

One implication is that scientific inquiry is not a private practice. It is a public practice available for others to see and learn from. Notice how different this is from everyday learning. When you happen to learn something from your everyday experience, often only you gain from the experience. The fact that research is a public practice means it is also a social one. It is best conducted by interacting with others along the way: soliciting feedback at each phase, taking opportunities to present work-in-progress, and benefitting from the advice of others.

A second implication is that you, as the researcher, must be committed to sharing what you are doing and what you are learning in an open and transparent way. This allows all phases of your work to be scrutinized and critiqued. This is what gives your work credibility. The reliability or trustworthiness of your findings depends on your colleagues recognizing that you have used all appropriate methods to maximize the chances that your claims are justified by the data.

A third implication of viewing scientific inquiry as a collective enterprise is the reverse of the second—you must be committed to receiving comments from others. You must treat your colleagues as fair and honest critics even though it might sometimes feel otherwise. You must appreciate their job, which is to remain skeptical while scrutinizing what you have done in considerable detail. To provide the best help to you, they must remain skeptical about your conclusions (when, for example, the data are difficult for them to interpret) until you offer a convincing logical argument based on the information you share. A rather harsh but good-to-remember statement of the role of your friendly critics was voiced by Karl Popper, a well-known twentieth century philosopher of science: “. . . if you are interested in the problem which I tried to solve by my tentative assertion, you may help me by criticizing it as severely as you can” (Popper, 1968, p. 27).

A final implication of this third descriptor is that, as someone engaged in scientific inquiry, you have no choice but to update your thinking when the data support a different conclusion. This applies to your own data as well as to those of others. When data clearly point to a specific claim, even one that is quite different than you expected, you must reconsider your position. If the outcome is replicated multiple times, you need to adjust your thinking accordingly. Scientific inquiry does not let you pick and choose which data to believe; it mandates that everyone update their thinking when the data warrant an update.

Doing Scientific Inquiry

We define scientific inquiry in an operational sense—what does it mean to do scientific inquiry? What kind of process would satisfy all three descriptors: carefully planning an experience in advance; observing and trying to explain what you see; and, contributing to updating everyone’s thinking about an important phenomenon?

We define scientific inquiry as formulating , testing , and revising hypotheses about phenomena of interest.

Of course, we are not the only ones who define it in this way. The definition for the scientific method posted by the editors of Britannica is: “a researcher develops a hypothesis, tests it through various means, and then modifies the hypothesis on the basis of the outcome of the tests and experiments” (Britannica, n.d. ).

An image represents the scientific inquiry definition given by the editors of Britannica and also defines the hypothesis on the basis of the experiments.

Notice how defining scientific inquiry this way satisfies each of the descriptors. “Carefully planning an experience in advance” is exactly what happens when formulating a hypothesis about a phenomenon of interest and thinking about how to test it. “ Observing a phenomenon” occurs when testing a hypothesis, and “ explaining ” what is found is required when revising a hypothesis based on the data. Finally, “updating everyone’s thinking” comes from comparing publicly the original with the revised hypothesis.

Doing scientific inquiry, as we have defined it, underscores the value of accumulating knowledge rather than generating random bits of knowledge. Formulating, testing, and revising hypotheses is an ongoing process, with each revised hypothesis begging for another test, whether by the same researcher or by new researchers. The editors of Britannica signaled this cyclic process by adding the following phrase to their definition of the scientific method: “The modified hypothesis is then retested, further modified, and tested again.” Scientific inquiry creates a process that encourages each study to build on the studies that have gone before. Through collective engagement in this process of building study on top of study, the scientific community works together to update its thinking.

Before exploring more fully the meaning of “formulating, testing, and revising hypotheses,” we need to acknowledge that this is not the only way researchers define research. Some researchers prefer a less formal definition, one that includes more serendipity, less planning, less explanation. You might have come across more open definitions such as “research is finding out about something.” We prefer the tighter hypothesis formulation, testing, and revision definition because we believe it provides a single, coherent map for conducting research that addresses many of the thorny problems educational researchers encounter. We believe it is the most useful orientation toward research and the most helpful to learn as a beginning researcher.

A final clarification of our definition is that it applies equally to qualitative and quantitative research. This is a familiar distinction in education that has generated much discussion. You might think our definition favors quantitative methods over qualitative methods because the language of hypothesis formulation and testing is often associated with quantitative methods. In fact, we do not favor one method over another. In Chap. 4 , we will illustrate how our definition fits research using a range of quantitative and qualitative methods.

Exercise 1.4

Look for ways to extend what the field knows in an area that has already received attention by other researchers. Specifically, you can search for a program of research carried out by more experienced researchers that has some revised hypotheses that remain untested. Identify a revised hypothesis that you might like to test.

Unpacking the Terms Formulating, Testing, and Revising Hypotheses

To get a full sense of the definition of scientific inquiry we will use throughout this book, it is helpful to spend a little time with each of the key terms.

We first want to make clear that we use the term “hypothesis” as it is defined in most dictionaries and as it used in many scientific fields rather than as it is usually defined in educational statistics courses. By “hypothesis,” we do not mean a null hypothesis that is accepted or rejected by statistical analysis. Rather, we use “hypothesis” in the sense conveyed by the following definitions: “An idea or explanation for something that is based on known facts but has not yet been proved” (Cambridge University Press, n.d. ), and “An unproved theory, proposition, or supposition, tentatively accepted to explain certain facts and to provide a basis for further investigation or argument” (Agnes & Guralnik, 2008 ).

We distinguish two parts to “hypotheses.” Hypotheses consist of predictions and rationales . Predictions are statements about what you expect to find when you inquire about something. Rationales are explanations for why you made the predictions you did, why you believe your predictions are correct. So, for us “formulating hypotheses” means making explicit predictions and developing rationales for the predictions.

“Testing hypotheses” means making observations that allow you to assess in what ways your predictions were correct and in what ways they were incorrect. In education research, it is rarely useful to think of your predictions as either right or wrong. Because of the complexity of most issues you will investigate, most predictions will be right in some ways and wrong in others.

By studying the observations you make (data you collect) to test your hypotheses, you can revise your hypotheses to better align with the observations. This means revising your predictions plus revising your rationales to justify your adjusted predictions. Even though you might not run another test, formulating revised hypotheses is an essential part of conducting a research study. Comparing your original and revised hypotheses informs everyone of what you learned by conducting your study. In addition, a revised hypothesis sets the stage for you or someone else to extend your study and accumulate more knowledge of the phenomenon.

We should note that not everyone makes a clear distinction between predictions and rationales as two aspects of hypotheses. In fact, common, non-scientific uses of the word “hypothesis” may limit it to only a prediction or only an explanation (or rationale). We choose to explicitly include both prediction and rationale in our definition of hypothesis, not because we assert this should be the universal definition, but because we want to foreground the importance of both parts acting in concert. Using “hypothesis” to represent both prediction and rationale could hide the two aspects, but we make them explicit because they provide different kinds of information. It is usually easier to make predictions than develop rationales because predictions can be guesses, hunches, or gut feelings about which you have little confidence. Developing a compelling rationale requires careful thought plus reading what other researchers have found plus talking with your colleagues. Often, while you are developing your rationale you will find good reasons to change your predictions. Developing good rationales is the engine that drives scientific inquiry. Rationales are essentially descriptions of how much you know about the phenomenon you are studying. Throughout this guide, we will elaborate on how developing good rationales drives scientific inquiry. For now, we simply note that it can sharpen your predictions and help you to interpret your data as you test your hypotheses.

An image represents the rationale and the prediction for the scientific inquiry and different types of information provided by the terms.

Hypotheses in education research take a variety of forms or types. This is because there are a variety of phenomena that can be investigated. Investigating educational phenomena is sometimes best done using qualitative methods, sometimes using quantitative methods, and most often using mixed methods (e.g., Hay, 2016 ; Weis et al. 2019a ; Weisner, 2005 ). This means that, given our definition, hypotheses are equally applicable to qualitative and quantitative investigations.

Hypotheses take different forms when they are used to investigate different kinds of phenomena. Two very different activities in education could be labeled conducting experiments and descriptions. In an experiment, a hypothesis makes a prediction about anticipated changes, say the changes that occur when a treatment or intervention is applied. You might investigate how students’ thinking changes during a particular kind of instruction.

A second type of hypothesis, relevant for descriptive research, makes a prediction about what you will find when you investigate and describe the nature of a situation. The goal is to understand a situation as it exists rather than to understand a change from one situation to another. In this case, your prediction is what you expect to observe. Your rationale is the set of reasons for making this prediction; it is your current explanation for why the situation will look like it does.

You will probably read, if you have not already, that some researchers say you do not need a prediction to conduct a descriptive study. We will discuss this point of view in Chap. 2 . For now, we simply claim that scientific inquiry, as we have defined it, applies to all kinds of research studies. Descriptive studies, like others, not only benefit from formulating, testing, and revising hypotheses, but also need hypothesis formulating, testing, and revising.

One reason we define research as formulating, testing, and revising hypotheses is that if you think of research in this way you are less likely to go wrong. It is a useful guide for the entire process, as we will describe in detail in the chapters ahead. For example, as you build the rationale for your predictions, you are constructing the theoretical framework for your study (Chap. 3 ). As you work out the methods you will use to test your hypothesis, every decision you make will be based on asking, “Will this help me formulate or test or revise my hypothesis?” (Chap. 4 ). As you interpret the results of testing your predictions, you will compare them to what you predicted and examine the differences, focusing on how you must revise your hypotheses (Chap. 5 ). By anchoring the process to formulating, testing, and revising hypotheses, you will make smart decisions that yield a coherent and well-designed study.

Exercise 1.5

Compare the concept of formulating, testing, and revising hypotheses with the descriptions of scientific inquiry contained in Scientific Research in Education (NRC, 2002 ). How are they similar or different?

Exercise 1.6

Provide an example to illustrate and emphasize the differences between everyday learning/thinking and scientific inquiry.

Learning from Doing Scientific Inquiry

We noted earlier that a measure of what you have learned by conducting a research study is found in the differences between your original hypothesis and your revised hypothesis based on the data you collected to test your hypothesis. We will elaborate this statement in later chapters, but we preview our argument here.

Even before collecting data, scientific inquiry requires cycles of making a prediction, developing a rationale, refining your predictions, reading and studying more to strengthen your rationale, refining your predictions again, and so forth. And, even if you have run through several such cycles, you still will likely find that when you test your prediction you will be partly right and partly wrong. The results will support some parts of your predictions but not others, or the results will “kind of” support your predictions. A critical part of scientific inquiry is making sense of your results by interpreting them against your predictions. Carefully describing what aspects of your data supported your predictions, what aspects did not, and what data fell outside of any predictions is not an easy task, but you cannot learn from your study without doing this analysis.

An image represents the cycle of events that take place before making predictions, developing the rationale, and studying the prediction and rationale multiple times.

Analyzing the matches and mismatches between your predictions and your data allows you to formulate different rationales that would have accounted for more of the data. The best revised rationale is the one that accounts for the most data. Once you have revised your rationales, you can think about the predictions they best justify or explain. It is by comparing your original rationales to your new rationales that you can sort out what you learned from your study.

Suppose your study was an experiment. Maybe you were investigating the effects of a new instructional intervention on students’ learning. Your original rationale was your explanation for why the intervention would change the learning outcomes in a particular way. Your revised rationale explained why the changes that you observed occurred like they did and why your revised predictions are better. Maybe your original rationale focused on the potential of the activities if they were implemented in ideal ways and your revised rationale included the factors that are likely to affect how teachers implement them. By comparing the before and after rationales, you are describing what you learned—what you can explain now that you could not before. Another way of saying this is that you are describing how much more you understand now than before you conducted your study.

Revised predictions based on carefully planned and collected data usually exhibit some of the following features compared with the originals: more precision, more completeness, and broader scope. Revised rationales have more explanatory power and become more complete, more aligned with the new predictions, sharper, and overall more convincing.

Part II. Why Do Educators Do Research?

Doing scientific inquiry is a lot of work. Each phase of the process takes time, and you will often cycle back to improve earlier phases as you engage in later phases. Because of the significant effort required, you should make sure your study is worth it. So, from the beginning, you should think about the purpose of your study. Why do you want to do it? And, because research is a social practice, you should also think about whether the results of your study are likely to be important and significant to the education community.

If you are doing research in the way we have described—as scientific inquiry—then one purpose of your study is to understand , not just to describe or evaluate or report. As we noted earlier, when you formulate hypotheses, you are developing rationales that explain why things might be like they are. In our view, trying to understand and explain is what separates research from other kinds of activities, like evaluating or describing.

One reason understanding is so important is that it allows researchers to see how or why something works like it does. When you see how something works, you are better able to predict how it might work in other contexts, under other conditions. And, because conditions, or contextual factors, matter a lot in education, gaining insights into applying your findings to other contexts increases the contributions of your work and its importance to the broader education community.

Consequently, the purposes of research studies in education often include the more specific aim of identifying and understanding the conditions under which the phenomena being studied work like the observations suggest. A classic example of this kind of study in mathematics education was reported by William Brownell and Harold Moser in 1949 . They were trying to establish which method of subtracting whole numbers could be taught most effectively—the regrouping method or the equal additions method. However, they realized that effectiveness might depend on the conditions under which the methods were taught—“meaningfully” versus “mechanically.” So, they designed a study that crossed the two instructional approaches with the two different methods (regrouping and equal additions). Among other results, they found that these conditions did matter. The regrouping method was more effective under the meaningful condition than the mechanical condition, but the same was not true for the equal additions algorithm.

What do education researchers want to understand? In our view, the ultimate goal of education is to offer all students the best possible learning opportunities. So, we believe the ultimate purpose of scientific inquiry in education is to develop understanding that supports the improvement of learning opportunities for all students. We say “ultimate” because there are lots of issues that must be understood to improve learning opportunities for all students. Hypotheses about many aspects of education are connected, ultimately, to students’ learning. For example, formulating and testing a hypothesis that preservice teachers need to engage in particular kinds of activities in their coursework in order to teach particular topics well is, ultimately, connected to improving students’ learning opportunities. So is hypothesizing that school districts often devote relatively few resources to instructional leadership training or hypothesizing that positioning mathematics as a tool students can use to combat social injustice can help students see the relevance of mathematics to their lives.

We do not exclude the importance of research on educational issues more removed from improving students’ learning opportunities, but we do think the argument for their importance will be more difficult to make. If there is no way to imagine a connection between your hypothesis and improving learning opportunities for students, even a distant connection, we recommend you reconsider whether it is an important hypothesis within the education community.

Notice that we said the ultimate goal of education is to offer all students the best possible learning opportunities. For too long, educators have been satisfied with a goal of offering rich learning opportunities for lots of students, sometimes even for just the majority of students, but not necessarily for all students. Evaluations of success often are based on outcomes that show high averages. In other words, if many students have learned something, or even a smaller number have learned a lot, educators may have been satisfied. The problem is that there is usually a pattern in the groups of students who receive lower quality opportunities—students of color and students who live in poor areas, urban and rural. This is not acceptable. Consequently, we emphasize the premise that the purpose of education research is to offer rich learning opportunities to all students.

One way to make sure you will be able to convince others of the importance of your study is to consider investigating some aspect of teachers’ shared instructional problems. Historically, researchers in education have set their own research agendas, regardless of the problems teachers are facing in schools. It is increasingly recognized that teachers have had trouble applying to their own classrooms what researchers find. To address this problem, a researcher could partner with a teacher—better yet, a small group of teachers—and talk with them about instructional problems they all share. These discussions can create a rich pool of problems researchers can consider. If researchers pursued one of these problems (preferably alongside teachers), the connection to improving learning opportunities for all students could be direct and immediate. “Grounding a research question in instructional problems that are experienced across multiple teachers’ classrooms helps to ensure that the answer to the question will be of sufficient scope to be relevant and significant beyond the local context” (Cai et al., 2019b , p. 115).

As a beginning researcher, determining the relevance and importance of a research problem is especially challenging. We recommend talking with advisors, other experienced researchers, and peers to test the educational importance of possible research problems and topics of study. You will also learn much more about the issue of research importance when you read Chap. 5 .

Exercise 1.7

Identify a problem in education that is closely connected to improving learning opportunities and a problem that has a less close connection. For each problem, write a brief argument (like a logical sequence of if-then statements) that connects the problem to all students’ learning opportunities.

Part III. Conducting Research as a Practice of Failing Productively

Scientific inquiry involves formulating hypotheses about phenomena that are not fully understood—by you or anyone else. Even if you are able to inform your hypotheses with lots of knowledge that has already been accumulated, you are likely to find that your prediction is not entirely accurate. This is normal. Remember, scientific inquiry is a process of constantly updating your thinking. More and better information means revising your thinking, again, and again, and again. Because you never fully understand a complicated phenomenon and your hypotheses never produce completely accurate predictions, it is easy to believe you are somehow failing.

The trick is to fail upward, to fail to predict accurately in ways that inform your next hypothesis so you can make a better prediction. Some of the best-known researchers in education have been open and honest about the many times their predictions were wrong and, based on the results of their studies and those of others, they continuously updated their thinking and changed their hypotheses.

A striking example of publicly revising (actually reversing) hypotheses due to incorrect predictions is found in the work of Lee J. Cronbach, one of the most distinguished educational psychologists of the twentieth century. In 1955, Cronbach delivered his presidential address to the American Psychological Association. Titling it “Two Disciplines of Scientific Psychology,” Cronbach proposed a rapprochement between two research approaches—correlational studies that focused on individual differences and experimental studies that focused on instructional treatments controlling for individual differences. (We will examine different research approaches in Chap. 4 ). If these approaches could be brought together, reasoned Cronbach ( 1957 ), researchers could find interactions between individual characteristics and treatments (aptitude-treatment interactions or ATIs), fitting the best treatments to different individuals.

In 1975, after years of research by many researchers looking for ATIs, Cronbach acknowledged the evidence for simple, useful ATIs had not been found. Even when trying to find interactions between a few variables that could provide instructional guidance, the analysis, said Cronbach, creates “a hall of mirrors that extends to infinity, tormenting even the boldest investigators and defeating even ambitious designs” (Cronbach, 1975 , p. 119).

As he was reflecting back on his work, Cronbach ( 1986 ) recommended moving away from documenting instructional effects through statistical inference (an approach he had championed for much of his career) and toward approaches that probe the reasons for these effects, approaches that provide a “full account of events in a time, place, and context” (Cronbach, 1986 , p. 104). This is a remarkable change in hypotheses, a change based on data and made fully transparent. Cronbach understood the value of failing productively.

Closer to home, in a less dramatic example, one of us began a line of scientific inquiry into how to prepare elementary preservice teachers to teach early algebra. Teaching early algebra meant engaging elementary students in early forms of algebraic reasoning. Such reasoning should help them transition from arithmetic to algebra. To begin this line of inquiry, a set of activities for preservice teachers were developed. Even though the activities were based on well-supported hypotheses, they largely failed to engage preservice teachers as predicted because of unanticipated challenges the preservice teachers faced. To capitalize on this failure, follow-up studies were conducted, first to better understand elementary preservice teachers’ challenges with preparing to teach early algebra, and then to better support preservice teachers in navigating these challenges. In this example, the initial failure was a necessary step in the researchers’ scientific inquiry and furthered the researchers’ understanding of this issue.

We present another example of failing productively in Chap. 2 . That example emerges from recounting the history of a well-known research program in mathematics education.

Making mistakes is an inherent part of doing scientific research. Conducting a study is rarely a smooth path from beginning to end. We recommend that you keep the following things in mind as you begin a career of conducting research in education.

First, do not get discouraged when you make mistakes; do not fall into the trap of feeling like you are not capable of doing research because you make too many errors.

Second, learn from your mistakes. Do not ignore your mistakes or treat them as errors that you simply need to forget and move past. Mistakes are rich sites for learning—in research just as in other fields of study.

Third, by reflecting on your mistakes, you can learn to make better mistakes, mistakes that inform you about a productive next step. You will not be able to eliminate your mistakes, but you can set a goal of making better and better mistakes.

Exercise 1.8

How does scientific inquiry differ from everyday learning in giving you the tools to fail upward? You may find helpful perspectives on this question in other resources on science and scientific inquiry (e.g., Failure: Why Science is So Successful by Firestein, 2015).

Exercise 1.9

Use what you have learned in this chapter to write a new definition of scientific inquiry. Compare this definition with the one you wrote before reading this chapter. If you are reading this book as part of a course, compare your definition with your colleagues’ definitions. Develop a consensus definition with everyone in the course.

Part IV. Preview of Chap. 2

Now that you have a good idea of what research is, at least of what we believe research is, the next step is to think about how to actually begin doing research. This means how to begin formulating, testing, and revising hypotheses. As for all phases of scientific inquiry, there are lots of things to think about. Because it is critical to start well, we devote Chap. 2 to getting started with formulating hypotheses.

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Hiebert, J., Cai, J., Hwang, S., Morris, A.K., Hohensee, C. (2023). What Is Research, and Why Do People Do It?. In: Doing Research: A New Researcher’s Guide. Research in Mathematics Education. Springer, Cham. https://doi.org/10.1007/978-3-031-19078-0_1

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What Is the Importance of Research? 5 Reasons Why Research is Critical

by Logan Bessant | Nov 16, 2021 | Science

Most of us appreciate that research is a crucial part of medical advancement. But what exactly is the importance of research? In short, it is critical in the development of new medicines as well as ensuring that existing treatments are used to their full potential.

Research can bridge knowledge gaps and change the way healthcare practitioners work by providing solutions to previously unknown questions.

In this post, we’ll discuss the importance of research and its impact on medical breakthroughs.

The Importance Of Health Research

The purpose of studying is to gather information and evidence, inform actions, and contribute to the overall knowledge of a certain field. None of this is possible without research.

Understanding how to conduct research and the importance of it may seem like a very simple idea to some, but in reality, it’s more than conducting a quick browser search and reading a few chapters in a textbook.

No matter what career field you are in, there is always more to learn. Even for people who hold a Doctor of Philosophy (PhD) in their field of study, there is always some sort of unknown that can be researched. Delving into this unlocks the unknowns, letting you explore the world from different perspectives and fueling a deeper understanding of how the universe works.

To make things a little more specific, this concept can be clearly applied in any healthcare scenario. Health research has an incredibly high value to society as it provides important information about disease trends and risk factors, outcomes of treatments, patterns of care, and health care costs and use. All of these factors as well as many more are usually researched through a clinical trial.

What Is The Importance Of Clinical Research?

Clinical trials are a type of research that provides information about a new test or treatment. They are usually carried out to find out what, or if, there are any effects of these procedures or drugs on the human body.

All legitimate clinical trials are carefully designed, reviewed and completed, and need to be approved by professionals before they can begin. They also play a vital part in the advancement of medical research including:

Providing new and good information on which types of drugs are more effective.
Bringing new treatments such as medicines, vaccines and devices into the field.
Testing the safety and efficacy of a new drug before it is brought to market and used in clinical practice.
Giving the opportunity for more effective treatments to benefit millions of lives both now and in the future.
Enhancing health, lengthening life, and reducing the burdens of illness and disability.

This all plays back to clinical research as it opens doors to advancing prevention, as well as providing treatments and cures for diseases and disabilities. Clinical trial volunteer participants are essential to this progress which further supports the need for the importance of research to be well-known amongst healthcare professionals, students and the general public.

The image shows a researchers hand holding a magnifying glass to signify the importance of research.

Five Reasons Why Research is Critical

Research is vital for almost everyone irrespective of their career field. From doctors to lawyers to students to scientists, research is the key to better work.

Increases quality of life

Research is the backbone of any major scientific or medical breakthrough. None of the advanced treatments or life-saving discoveries used to treat patients today would be available if it wasn’t for the detailed and intricate work carried out by scientists, doctors and healthcare professionals over the past decade.

This improves quality of life because it can help us find out important facts connected to the researched subject. For example, universities across the globe are now studying a wide variety of things from how technology can help breed healthier livestock, to how dance can provide long-term benefits to people living with Parkinson’s.

For both of these studies, quality of life is improved. Farmers can use technology to breed healthier livestock which in turn provides them with a better turnover, and people who suffer from Parkinson’s disease can find a way to reduce their symptoms and ease their stress.

Research is a catalyst for solving the world’s most pressing issues. Even though the complexity of these issues evolves over time, they always provide a glimmer of hope to improving lives and making processes simpler.

Builds up credibility

People are willing to listen and trust someone with new information on one condition – it’s backed up. And that’s exactly where research comes in. Conducting studies on new and unfamiliar subjects, and achieving the desired or expected outcome, can help people accept the unknown.

However, this goes without saying that your research should be focused on the best sources. It is easy for people to poke holes in your findings if your studies have not been carried out correctly, or there is no reliable data to back them up.

This way once you have done completed your research, you can speak with confidence about your findings within your field of study.

Drives progress forward

It is with thanks to scientific research that many diseases once thought incurable, now have treatments. For example, before the 1930s, anyone who contracted a bacterial infection had a high probability of death. There simply was no treatment for even the mildest of infections as, at the time, it was thought that nothing could kill bacteria in the gut.

When antibiotics were discovered and researched in 1928, it was considered one of the biggest breakthroughs in the medical field. This goes to show how much research drives progress forward, and how it is also responsible for the evolution of technology .

Today vaccines, diagnoses and treatments can all be simplified with the progression of medical research, making us question just what research can achieve in the future.

Engages curiosity

The acts of searching for information and thinking critically serve as food for the brain, allowing our inherent creativity and logic to remain active. Aside from the fact that this curiosity plays such a huge part within research, it is also proven that exercising our minds can reduce anxiety and our chances of developing mental illnesses in the future.

Without our natural thirst and our constant need to ask ‘why?’ and ‘how?’ many important theories would not have been put forward and life-changing discoveries would not have been made. The best part is that the research process itself rewards this curiosity.

Research opens you up to different opinions and new ideas which can take a proposed question and turn into a real-life concept. It also builds discerning and analytical skills which are always beneficial in many career fields – not just scientific ones.

Increases awareness

The main goal of any research study is to increase awareness, whether it’s contemplating new concepts with peers from work or attracting the attention of the general public surrounding a certain issue.

Around the globe, research is used to help raise awareness of issues like climate change, racial discrimination, and gender inequality. Without consistent and reliable studies to back up these issues, it would be hard to convenience people that there is a problem that needs to be solved in the first place.

The problem is that social media has become a place where fake news spreads like a wildfire, and with so many incorrect facts out there it can be hard to know who to trust. Assessing the integrity of the news source and checking for similar news on legitimate media outlets can help prove right from wrong.

This can pinpoint fake research articles and raises awareness of just how important fact-checking can be.

The Importance Of Research To Students

It is not a hidden fact that research can be mentally draining, which is why most students avoid it like the plague. But the matter of fact is that no matter which career path you choose to go down, research will inevitably be a part of it.

But why is research so important to students ? The truth is without research, any intellectual growth is pretty much impossible. It acts as a knowledge-building tool that can guide you up to the different levels of learning. Even if you are an expert in your field, there is always more to uncover, or if you are studying an entirely new topic, research can help you build a unique perspective about it.

For example, if you are looking into a topic for the first time, it might be confusing knowing where to begin. Most of the time you have an overwhelming amount of information to sort through whether that be reading through scientific journals online or getting through a pile of textbooks. Research helps to narrow down to the most important points you need so you are able to find what you need to succeed quickly and easily.

It can also open up great doors in the working world. Employers, especially those in the scientific and medical fields, are always looking for skilled people to hire. Undertaking research and completing studies within your academic phase can show just how multi-skilled you are and give you the resources to tackle any tasks given to you in the workplace.

The Importance Of Research Methodology

There are many different types of research that can be done, each one with its unique methodology and features that have been designed to use in specific settings.

When showing your research to others, they will want to be guaranteed that your proposed inquiry needs asking, and that your methodology is equipt to answer your inquiry and will convey the results you’re looking for.

That’s why it’s so important to choose the right methodology for your study. Knowing what the different types of research are and what each of them focuses on can allow you to plan your project to better utilise the most appropriate methodologies and techniques available. Here are some of the most common types:

Theoretical Research: This attempts to answer a question based on the unknown. This could include studying phenomena or ideas whose conclusions may not have any immediate real-world application. Commonly used in physics and astronomy applications.
Applied Research: Mainly for development purposes, this seeks to solve a practical problem that draws on theory to generate practical scientific knowledge. Commonly used in STEM and medical fields.
Exploratory Research: Used to investigate a problem that is not clearly defined, this type of research can be used to establish cause-and-effect relationships. It can be applied in a wide range of fields from business to literature.
Correlational Research: This identifies the relationship between two or more variables to see if and how they interact with each other. Very commonly used in psychological and statistical applications.

The Importance Of Qualitative Research

This type of research is most commonly used in scientific and social applications. It collects, compares and interprets information to specifically address the “how” and “why” research questions.

Qualitative research allows you to ask questions that cannot be easily put into numbers to understand human experience because you’re not limited by survey instruments with a fixed set of possible responses.

Information can be gathered in numerous ways including interviews, focus groups and ethnographic research which is then all reported in the language of the informant instead of statistical analyses.

This type of research is important because they do not usually require a hypothesis to be carried out. Instead, it is an open-ended research approach that can be adapted and changed while the study is ongoing. This enhances the quality of the data and insights generated and creates a much more unique set of data to analyse.

The Process Of Scientific Research

No matter the type of research completed, it will be shared and read by others. Whether this is with colleagues at work, peers at university, or whilst it’s being reviewed and repeated during secondary analysis.

A reliable procedure is necessary in order to obtain the best information which is why it’s important to have a plan. Here are the six basic steps that apply in any research process.

Observation and asking questions: Seeing a phenomenon and asking yourself ‘How, What, When, Who, Which, Why, or Where?’. It is best that these questions are measurable and answerable through experimentation.
Gathering information: Doing some background research to learn what is already known about the topic, and what you need to find out.
Forming a hypothesis: Constructing a tentative statement to study.
Testing the hypothesis: Conducting an experiment to test the accuracy of your statement. This is a way to gather data about your predictions and should be easy to repeat.
Making conclusions: Analysing the data from the experiment(s) and drawing conclusions about whether they support or contradict your hypothesis.
Reporting: Presenting your findings in a clear way to communicate with others. This could include making a video, writing a report or giving a presentation to illustrate your findings.

Although most scientists and researchers use this method, it may be tweaked between one study and another. Skipping or repeating steps is common within, however the core principles of the research process still apply.

By clearly explaining the steps and procedures used throughout the study, other researchers can then replicate the results. This is especially beneficial for peer reviews that try to replicate the results to ensure that the study is sound.

What Is The Importance Of Research In Everyday Life?

Conducting a research study and comparing it to how important it is in everyday life are two very different things.

Carrying out research allows you to gain a deeper understanding of science and medicine by developing research questions and letting your curiosity blossom. You can experience what it is like to work in a lab and learn about the whole reasoning behind the scientific process. But how does that impact everyday life?

Simply put, it allows us to disprove lies and support truths. This can help society to develop a confident attitude and not believe everything as easily, especially with the rise of fake news.

Research is the best and reliable way to understand and act on the complexities of various issues that we as humans are facing. From technology to healthcare to defence to climate change, carrying out studies is the only safe and reliable way to face our future.

Not only does research sharpen our brains, but also helps us to understand various issues of life in a much larger manner, always leaving us questioning everything and fuelling our need for answers.

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10 Reasons Why Research is Important

No matter what career field you’re in or how high up you are, there’s always more to learn . The same applies to your personal life. No matter how many experiences you have or how diverse your social circle, there are things you don’t know. Research unlocks the unknowns, lets you explore the world from different perspectives, and fuels a deeper understanding. In some areas, research is an essential part of success. In others, it may not be absolutely necessary, but it has many benefits. Here are ten reasons why research is important:

#1. Research expands your knowledge base

The most obvious reason to do research is that you’ll learn more. There’s always more to learn about a topic, even if you are already well-versed in it. If you aren’t, research allows you to build on any personal experience you have with the subject. The process of research opens up new opportunities for learning and growth.

#2. Research gives you the latest information

Research encourages you to find the most recent information available . In certain fields, especially scientific ones, there’s always new information and discoveries being made. Staying updated prevents you from falling behind and giving info that’s inaccurate or doesn’t paint the whole picture. With the latest info, you’ll be better equipped to talk about a subject and build on ideas.

#3. Research helps you know what you’re up against

In business, you’ll have competition. Researching your competitors and what they’re up to helps you formulate your plans and strategies. You can figure out what sets you apart. In other types of research, like medicine, your research might identify diseases, classify symptoms, and come up with ways to tackle them. Even if your “enemy” isn’t an actual person or competitor, there’s always some kind of antagonist force or problem that research can help you deal with.

#4. Research builds your credibility

People will take what you have to say more seriously when they can tell you’re informed. Doing research gives you a solid foundation on which you can build your ideas and opinions. You can speak with confidence about what you know is accurate. When you’ve done the research, it’s much harder for someone to poke holes in what you’re saying. Your research should be focused on the best sources. If your “research” consists of opinions from non-experts, you won’t be very credible. When your research is good, though, people are more likely to pay attention.

#5. Research helps you narrow your scope

When you’re circling a topic for the first time, you might not be exactly sure where to start. Most of the time, the amount of work ahead of you is overwhelming. Whether you’re writing a paper or formulating a business plan, it’s important to narrow the scope at some point. Research helps you identify the most unique and/or important themes. You can choose the themes that fit best with the project and its goals.

#6. Research teaches you better discernment

Doing a lot of research helps you sift through low-quality and high-quality information. The more research you do on a topic, the better you’ll get at discerning what’s accurate and what’s not. You’ll also get better at discerning the gray areas where information may be technically correct but used to draw questionable conclusions.

#7. Research introduces you to new ideas

You may already have opinions and ideas about a topic when you start researching. The more you research, the more viewpoints you’ll come across. This encourages you to entertain new ideas and perhaps take a closer look at yours. You might change your mind about something or, at least, figure out how to position your ideas as the best ones.

#8. Research helps with problem-solving

Whether it’s a personal or professional problem, it helps to look outside yourself for help. Depending on what the issue is, your research can focus on what others have done before. You might just need more information, so you can make an informed plan of attack and an informed decision. When you know you’ve collected good information, you’ll feel much more confident in your solution.

#9. Research helps you reach people

Research is used to help raise awareness of issues like climate change , racial discrimination, gender inequality , and more. Without hard facts, it’s very difficult to prove that climate change is getting worse or that gender inequality isn’t progressing as quickly as it should. The public needs to know what the facts are, so they have a clear idea of what “getting worse” or “not progressing” actually means. Research also entails going beyond the raw data and sharing real-life stories that have a more personal impact on people.

#10. Research encourages curiosity

Having curiosity and a love of learning take you far in life. Research opens you up to different opinions and new ideas. It also builds discerning and analytical skills. The research process rewards curiosity. When you’re committed to learning, you’re always in a place of growth. Curiosity is also good for your health. Studies show curiosity is associated with higher levels of positivity, better satisfaction with life, and lower anxiety.

1 Chapter 1: The Importance of Research Methods and Becoming an Informed Consumer of Research

Case study : student apprehension regarding research methods.

Research Study

Understanding and Measuring Student Apprehension in Criminal Justice Research Methods Courses 1

Research Question

How do we measure disinterest, relevance argumentation, and math anxiety experienced by students enrolled in research methods courses?

Methodology

It is said that “misery loves company,” so you are not alone in your apprehension and anxiety regarding your research methods course. The problem of student apprehension and anxiety related to taking a research methods course is not new and has been studied for over 25 years. Previously, such apprehension and anxiety appeared to be caused by math anxiety, especially as it applies to statistics. The authors of this article believe that student apprehension goes beyond math anxiety; that math anxiety is too simplistic of an explanation of student fear of research methods courses. Besides math anxiety, the researchers think that apprehension is caused by student indifference to the subject matter and irrelevance of the course because it does not apply to the “real world.” They state that student apprehension in research methods and statistics courses is due to three main factors:

Disinterest (D.);

Relevance Argumentation (RA.), and;

Math Anxiety (MA.).

Taken together, the reconceptualization is known as D.RA.MA., and the combination of these three factors constitutes the D.RA.MA. scale for research methods and statistics courses.

The researchers developed the D.RA.MA. scale by constructing survey questions to measure each factor in the scale (i.e., disinterest, relevance argumentation, and math anxiety). After they developed the survey, they tested it by distributing the survey to three criminal justice classes, totaling 80 students, from a midsized regional comprehensive university in the southern region of the United States. Higher scale scores demonstrate more disinterest, more relevance argumentation, or more math anxiety.

The D.RA.MA. scale consists of 20 survey questions. Ten questions were borrowed from an existing Math Anxiety scale developed by Betz 2 . The researchers then created five items to assess Disinterest and five items intended to measure Relevance Argumentation. The items for the D.RA.MA. scale are illustrated below.

Math Anxiety 3

I usually have been at ease in math classes.

Math does not scare me at all.

I am no good at math.

I don’t think that I could do advanced math.

Generally, I have been secure about attempting math.

For some reason, even though I study, math seems unusually hard for me.

Math has been my worst subject.

My mind goes blank and I am unable to think clearly when working in mathematics.

I think I could handle more difficult math.

I am not the type to do well in mathematics.

Relevance Argumentation 4

I will need research methods for my future work.

I view research methods as a subject that I will rarely use.

Research methods is not really useful for students who intend to work in Criminal Justice.

Knowing research methods will help me earn a living.

Research methods does not reflect the “real world.”

Research Disinterest 5

I am excited about taking research methods.

It would not bother me at all to take more research methods courses.

I expect a research methods class to be boring.

I don’t expect to learn much in research methods.

I really don’t care if I learn anything in research methods, as long as I get the requirement completed.

The Math Anxiety Scale responses for the 80 students ranged from 0 to 30 with a mean of 14, demonstrating a moderate level of math anxiety among the study participants. The responses for Relevance Argumentation ranged from 0 to 12 with a mean of 5.4 while those for Disinterest ranged from 1 to 15 with a mean of 7.0, demonstrating a moderate level of disinterest and relevance argumentation among students regarding research methods. Based on these findings, the study demonstrated that student apprehension regarding research methods courses goes beyond math anxiety and includes two additional factors; disinterest in the subject matter and irrelevance of research methods to the “real world.”

Limitations with the Study Procedure

This research study was designed to develop a broader measure of student apprehension in criminal justice research methods courses. Moving beyond just math anxiety, the researchers accomplished their objective by developing the D.RA.MA. scale; adding disinterest and relevance argumentation to the understanding of student apprehension regarding research methods. As is true for all research, this study is not without limitations. The biggest limitation of this study is the limited sample size. Only 80 students completed the survey. Although this is certainly a good start, similar research (i.e., replication) needs to be completed with larger student samples in different locations throughout the country before the actual quality of the D.RA.MA. scale can be determined.

Impact on Criminal Justice

The D.RA.MA. scale developed in this study identifies disinterest and relevance argumentation, in addition to math anxiety, as part of student apprehension and resistance to research methods. A variety of instructional strategies can be inferred from the D.RA.MA. survey. However, it is important for professors to recognize that no single approach will reduce research methods resistance and apprehension for all students. For example, discussing research methods in a popular culture framework may resonate with students and lead to engaged students who are more interested in the subject matter and identify with the relevance of research methods to criminal justice in general and the future careers of students, in particular. This approach may provide an effective means for combating student disinterest and relevance argumentation in criminal justice research methods courses. At a minimum, it is critical for professors to explain the relevance of research methods to the policies and practices of police, courts, and corrections. Students need to realize that research methods are essential tools for assessing agency policies and practices. Professors will always have D.RA.MA.-plagued students, but recognizing the problem and then developing effective strategies to connect with these students is the challenge all professors face. Experimenting with a multitude of teaching strategies to alleviate the math anxiety, relevance argumentation, and disinterest of criminal justice research methods students will result in more effective teaching and learning.

In This Chapter You Will Learn

What research is and why it is important to be an informed consumer of research

The sources of knowledge development and problems with each

How research methods can dispel myths about crime and the criminal justice system

The steps in the research process

How research has impacted criminal justice operations

Introduction

As noted in the chapter opening case study, it is expected that you have some anxiety and apprehension about taking this criminal justice research methods course. But, you have taken a significant step toward success in this course by opening up your research methods book, so congratulations are in order. You might have opened this book for a number of reasons. Perhaps it is the first day of class and you are ready to get started on the course material. Perhaps you have a quiz or exam soon. Perhaps the book has been gathering dust on your shelf since the first day of class and you are not doing well in your research methods class and are looking for the book to help with course improvement. Perhaps you are taking a research methods class in the future and are seeing if all the chatter among students is true.

No matter how you got here, two things are probably true. First, you are taking this research methods course because it is a requirement for your major. The bottom line is that most of the students who read this text are required to take a research methods course. While you may think studying research methods is irrelevant to your career goals, unnecessary, overly academic, or perhaps even intimidating, you probably must finish this course in order to graduate. Second, you have heard negative comments about this course. The negative comments mention the difficulty of the course and the relevance of the course (e.g., “I am going to be a police officer, so why do I need to take a research methods course?”). If you are like most students we have experienced in our research methods courses in the past, you are not initially interested in this course and are concerned about whether you will do well in it.

If you are concerned about the course, realize that you are not alone because most students are anxious about taking a research methods course. Also realize that your professor is well aware of student anxiety and apprehension regarding research methods. So, relax and do not think about the entire course and the entire book. Take the course content one chapter, one week at a time. One of the advantages of taking a research methods course is that you learn about the process of research methods. Each chapter builds upon the previous chapters, illustrating and discussing more about the research process. This is certainly an advantage, but it is also critical that you understand the initial chapters in this book so you are not confused with the content discussed in later chapters. In addition to anxiety and apprehension over the course material, research methods can be boring if you only read and learn about it with no particular purpose in mind. Although examples are prevalent throughout the book, as you read this material, it is recommended that you think about the relevancy and application of the topics covered in this book to your specific criminal justice interests. As you continue to read the book, think about how you might use the information you are reading in your current position or your intended profession.

The goal of this research methods book is to develop you into an informed consumer of research. Most, if not all, of your fellow classmates will never conduct their own research studies. However, every one of you will be exposed to research findings in your professional and personal lives for the remainder of your lives. You are exposed to research findings in the media (e.g., television, newspapers, and online), in personal interaction with others (e.g., friends and family, doctors, and professors), as well as in class. You should challenge yourself for this semester to keep a journal and document exposure to research in your daily life outside of college whether through the nightly news, newspapers, magazine articles, Internet, personal conversations, or other means. At the end of the semester, you will be amazed at the amount of research you are exposed to in a short period of time. This book is focused on research exposure and assisting you to become an educated consumer of research by providing you the skills necessary to differentiate between good and not so good research. Why should you believe research findings if the study is faulty? Without being an educated consumer of research, you will not be able to differentiate between useful and not useful research. This book is designed to remedy this problem.

This book was written to make your first encounter with research methods relevant and successful while providing you the tools necessary to become an educated consumer of research. Therefore, this book is written with the assumption that students have not had a prior class on research methods. In addition, this book assumes that practical and evaluative knowledge of research methods is more useful than theoretical knowledge of the development of research methods and the relationship between theory and research. Since the focus of this book is on consumerism, not researcher training, practical and evaluative knowledge is more useful than theoretical knowledge.

It is also important to understand that the professors who design academic programs in criminal justice at the associate and bachelor level believe that an understanding of research methods is important for students. That is why, more than likely, this research methods course is a required course in your degree program. These professors understand that a solid understanding of research methods will enrich the qualifications of students for employment and performance in their criminal justice careers.

As previously stated, the basic goal of this book is to make students, as future and possibly even current practitioners in the criminal justice system, better informed and more capable consumers of the results of criminal justice research. This goal is based on the belief that an understanding of research methods allows criminal justice practitioners to be better able to make use of the results of research as it applies to their work-related duties. In fact, thousands of research questions are asked and answered each year in research involving criminal justice and criminological topics. In addition, thousands of articles are published, papers presented at conferences, and reports prepared that provide answers to these questions. The ability to understand research gives practitioners knowledge of the most current information in their respective fields and the ability to use this knowledge to improve the effectiveness of criminal justice agencies.

How Do We Know What We Know? Sources of Knowledge

The reality is the understanding of crime and criminal justice system operations by the public is frequently the product of misguided assumptions, distorted interpretations, outright myths, and hardened ideological positions. 6 This is a bold statement that basically contends that most people’s knowledge of crime and criminal justice is inaccurate. But, how do these inaccuracies occur? Most people have learned what they know about crime and criminal justice system operations through some other means besides scientific research results and findings. Some of that knowledge is based on personal experience and common sense. Much of it is based on the information and images supported by politicians, governmental agencies, and especially the media. This section will discuss the mechanisms used to understand crime and criminal justice operations by the public. It is important to note that although this section will focus on the failings of these knowledge sources, they each can be, and certainly are, accurate at times, and thus are valuable sources of knowledge.

Knowledge from Authority

We gain knowledge from parents, teachers, experts, and others who are in positions of authority in our lives. When we accept something as being correct and true just because someone in a position of authority says it is true, we are using what is referred to as authority knowledge as a means of knowing. Authorities often expend significant time and effort to learn something, and we can benefit from their experience and work.

However, relying on authority as a means of knowing has limitations. It is easy to overestimate the expertise of other people. A person’s expertise is typically limited to a few core areas of significant knowledge; a person is not an expert in all areas. More specifically, criminal justice professors are not experts on all topics related to criminal justice. One professor may be an expert on corrections but know little about policing. If this professor discusses topics in policing in which he is not an expert, we may still assume he is right when he may be wrong. Authority figures may speak on fields they know little about. They can be completely wrong but we may believe them because of their status as an expert. Furthermore, an expert in one area may try to use his authority in an unrelated area. Other times, we have no idea of how the experts arrived at their knowledge. We just know they are experts in the topic area.

As I am writing this, I recall an example of authority knowledge that was wrong during my police academy training in the late 1980s. My academy training was about four years after the U.S. Supreme Court decision in Tennessee v. Garner. 7 In this case, the Court limited the use of deadly force by police to defense of life situations and incidents where the suspect committed a violent offense. Prior to the decision, the police in several states could use deadly force on any fleeing suspect accused of a felony offense. One day, the academy class was practicing mock traffic stops. During one of my mock traffic stops, I received information that the vehicle I stopped was stolen. The driver and passenger exited the vehicle and fled on foot. I did not use deadly force (this was a training exercise so was not real) against the suspects and was chastised by my instructor who insisted that I should have shot the suspects as they were fleeing. Training instructors, just like professors, convey authority knowledge but, in this case, the instructor was wrong. I was not legally authorized to use deadly force in the traffic stop scenario despite the insistence of my instructor to the contrary.

Politicians are sometimes taken as a source of authority knowledge about the law, crime, and criminal justice issues. Since they enact laws that directly impact the operations of the criminal justice system, we may assume they are an authority on crime and criminal justice. More specifically, we may assume that politicians know best about how to reduce crime and increase the effectiveness of the criminal justice system. However, history is rife with laws that sounded good on paper but had no impact on crime. For example, there is little evidence that sex offender registration protects the public from sexual predators or acts as a deterrent to repeat sex offenders even though every state has a law requiring convicted sex offenders to register with local authorities. Perhaps politicians are not the criminal justice experts some perceive them to be.

History is also full of criminal justice authorities that we now see as being misinformed. For example, Cesare Lombroso is the father of the positivist school of criminology. He is most readily recognized for his idea that some individuals are born criminal. He stated that criminals have certain unique biological characteristics, including large protruding jaws, high foreheads, flattened noses, and asymmetrical faces, to name a few. 8 These characteristics were similar to those found in primitive humans. Therefore, Lombroso argued that some individuals were genetic “throwbacks” to a more primitive time and were less evolved than other people and thus, were more likely to be criminals. Lombroso’s research has been discredited because he failed to compare criminals with noncriminals. By studying only criminals, he found characteristics that were common to criminals. However, if Lombroso had studied a group of noncriminals, he would have discovered that these biological characteristics are just as prevalent among noncriminals. This example involves authority knowledge that is supported by research but the research methods used were flawed. The errors of Lombroso seem obvious now, but what do we know today through authority knowledge that is inaccurate or will be proven wrong in the future?

Knowledge from Tradition

In addition to authority knowledge, people often rely on tradition for knowledge. Tradition knowledge relies on the knowledge of the past. Individuals accept something as true because that is the way things have always been so it must be right. A good example of tradition knowledge is preventive/random patrol. Ever since vehicles were brought into the police patrol function, police administrators assumed that having patrol officers drive around randomly in the communities they serve, while they are not answering calls for service, would prevent crime. If you were a patrol officer in the early 1970s and asked your supervisor, “Why do I drive around randomly throughout my assigned area when I am not answering a call for service?” the answer would have been, “That is the way we have always done patrol and random patrol reduces crime through deterrence.” The Kansas City Preventive Patrol Experiment challenged the tradition knowledge that preventive/random patrol reduces crime. The results of the study made it clear that the traditional practice of preventive/random patrol had little to no impact on reducing crime. This allowed police departments to develop other patrol deployment strategies such as directed patrol and “hot spots” policing since preventive patrol was seen as ineffective. The development of effective patrol deployment strategies continues today.

Knowledge from Common Sense

We frequently rely on common sense knowledge for what we know about crime and the criminal justice system because it “just makes sense.” For example, it “just makes sense” that if we send juvenile delinquents on a field trip to prison where they will see first hand the prison environment as well as be yelled at by actual prisoners, they will refrain from future delinquency. That is exactly what the program Scared Straight, originally developed in the 1970s, is designed to do. Scared Straight programs are still in existence today and are even the premise for the television show Beyond Scared Straight on the A&E television network. As originally created, the program was designed to decrease juvenile delinquency by bringing at-risk and delinquent juveniles into prison where they would be “scared straight” by inmates serving life sentences. Participants in the program were talked to and yelled at by the inmates in an effort to scare them. It was believed that the fear felt by the participants would lead to a discontinuation of their delinquent behavior so that they would not end up in prison themselves. This sounds like a good idea. It makes sense, and the program was initially touted as a success due to anecdotal evidence based on a few delinquents who turned their lives around after participation in the program.

However, evaluations of the program and others like it showed that the program was in fact unsuccessful. In the initial evaluation of the Scared Straight program, Finckenauer used a classic experimental design (discussed in Chapter 5), to evaluate the original “Lifer’s Program” at Rahway State Prison in New Jersey where the program was initially developed. 13 Juveniles were randomly assigned to an experimental group that attended the Scared Straight program and a control group that did not participate in the program. Results of the evaluation were not positive. Post-test measures revealed that juveniles who were assigned to the experimental group and participated in the program were actually more seriously delinquent afterwards than those who did not participate in the program. Also using an experimental design with random assignment, Yarborough evaluated the “Juvenile Offenders Learn Truth” (JOLT) program at the State Prison of Southern Michigan at Jackson. 14 This program was similar to that of the “Lifer’s Program,” only with fewer obscenities used by inmates. Post-test measurements were taken at two intervals, three and six months after program completion. Again, results were not positive. Findings revealed no significant differences in delinquency between those juveniles who attended the program and those who did not. Other experiments conducted on Scared Straight- type programs further revealed their inability to deter juveniles from further delinquency. 15 Despite the common sense popularity of these programs, the evaluations showed that Scared Straight programs do not reduce delinquency and, in some instances, may actually increase delinquency. The programs may actually do more harm than good. I guess that begs the question, “Why do we still do these types of programs?”

Scared Straight programs and other widely held common sense beliefs about crime and the criminal justice system are questionable, based on the available research evidence. Common sense is important in our daily lives and is frequently correct, but, at times, it also contains inaccuracies, misinformation, and even prejudice.

CLASSICS IN CJ RESEARCH

Is It Safe to Put Felons on Probation?

Research Study 9

In the mid-1970s, the number of offenders on probation began to significantly increase. By the mid-1980s, probation was the most frequently used sentence in most states and its use was becoming more common for felons, whereas previously, probation was typically limited to misdemeanor crimes and offenses committed by juveniles. Increasing numbers of felony offenders were being placed on probation because judges had no other alternative forms of punishment. Prisons were already operating above capacity due to rising crime rates. Despite the increase in the use of probation in the 1980s, few empirical studies of probation (particularly its use with felony offenders) had been published. In the early 1980s, the Rand Corporation conducted an extensive study of probation to learn more about the offenders sentenced to probation and the effectiveness of probation as a criminal sanction. At the time the study began, over one-third of California’s probation population were convicted felons. 10 This was the first large-scale study of felony probation.

Is it safe to put felons on probation?

Data for the study were obtained from the California Board of Prison Terms (CBPT). The Board had been collecting comprehensive data on all offenders sentenced to prison since 1978 and on a sample of adult males from 17 counties who received probation. From these two data sources, researchers selected a sample of male offenders who had been convicted of the following crimes: robbery, assault, burglary, theft, forgery, and drug offenses. These crimes were selected because an offender could receive either prison or probation if convicted. Approximately 16,500 male felony offenders were included in the study. For each offender, researchers had access to their personal characteristics, information on their crimes, court proceedings, and disposition.

Two main research questions were answered in this study. First, what were the recidivism rates for felony offenders who received probation? When assessing recidivism rates, the study found that the majority of offenders sentenced to probation recidivated during the follow-up period, which averaged 31 months. Overall, 65% of the sample of probationers were re-arrested and 51 % were charged with and convicted of another offense. A total of 18% were convicted of a violent crime.

The second research question asked, what were the characteristics of the probationers who recidivated? Property offenders were more likely to recidivate compared to violent or drug offenders. Researchers also discovered that probationers tended to recidivate by committing the same crime that placed them on probation. Rand researchers included time to recidivism in their analysis and found that property and violent offenders recidivated sooner than drug offenders. The median time to the first filed charge was five months for property offenders and eight months for violent offenders.

The issue of whether or not the findings would generalize to other counties in California and to other states was raised. Data for the study came from probation and prison records from two counties in California. These two counties were not randomly selected, but were chosen because of their large probation populations and the willingness of departments to provide information. Further, the probation departments in these counties had experienced significant budget cuts. Supervision may have become compromised as a result and this could have explained why these counties had high rates of recidivism. Studies of probation recidivism in other states have found recidivism rates to be much lower, suggesting the Rand results may not have applied elsewhere. 11 Several studies examining the effectiveness of probation and the factors correlated with probation outcomes were published after 1985. Much of this research failed to produce results consistent with the Rand study.

The Rand study of felony probation received a considerable amount of attention within the field of corrections. According to one scholar, the study was acclaimed as “the most important criminological research to be reported since World War II.” 12 The National Institute of Justice disseminated the report to criminal justice agencies across the country and even highlighted the study in their monthly newsletter. Today, the study remains one of the most highly cited pieces of corrections research.

According to Rand researchers, these findings raised serious doubts about the effectiveness of probation for felony offenders. Most of the felons sentenced to probation recidivated and researchers were unable to develop an accurate prediction model to improve the courts’ decision-making. The continued use of probation as a sanction for felony offenders appeared to be putting the public at risk. However, without adequate prison space, the courts had no other alternatives besides probation when sentencing offenders.

The researchers made several recommendations to address the limitations of using probation for felony offenders. First, it was recommended that states formally acknowledge that the purpose of probation had changed. Probation was originally used as a means of furthering the goal of rehabilitation in the correctional system. As the United States moved away from that goal in the late 1960s, the expectations of probation changed. Probation was now used as a way to exercise “restrictive supervision” over more serious offenders. Second, probation departments needed to redefine the responsibilities of their probation officers. Probation officers were now expected to be surveillance officers instead of treatment personnel, which required specialized training. In addition, states needed to explore the possibility of broadening the legal authority of its probation officers by allowing them to act as law enforcement officers if necessary. Third, states were advised to adopt a formal client management system that included risk/need assessments of every client. Such a system would help establish uniform, consistent treatment of those on probation and would also help departments allocate their resources efficiently and effectively. Fourth, researchers encouraged states to develop alternative forms of community punishment that offered more public protection than regular probation, which led to the development and use of intensive supervision probation, house arrest, electronic monitoring, day reporting centers, and other intermediate punishments.

Knowledge from Personal Experience

If you personally see something or if it actually happens to you, then you are likely to accept it as true and gain knowledge from the experience. Gaining knowledge through actual experiences is known as personal experience knowledge, and it has a powerful and lasting impact on everyone. Personal experiences are essential building blocks of knowledge and of what we believe to be true. The problem with knowledge gained from personal experiences is that personal experiences can be unique and unreliable, which can distort reality and lead us to believe things that are actually false.

How can events that someone personally experienced be wrong? The events are not wrong. Instead, the knowledge gained from the experience is wrong. For example, the research consistently shows that a person’s demeanor significantly impacts the decision-making of police officers. During a traffic stop, if a person is rude, disrespectful, and uncooperative to the officer, then the driver is more likely to receive a traffic citation than a warning. That is what the research on police discretion shows. However, if a person was rude and uncooperative to a police officer during a traffic stop and was let go without a citation, the person will gain knowledge from this personal experience. The knowledge gained may include that being disrespectful during future traffic stops will get this person out of future tickets. Not likely. The event is not wrong. Instead, the knowledge gained from the experience is wrong because being disrespectful to the police usually leads to more enforcement action taken by the police, not less.

As a student in criminal justice, you have probably experienced something similar in interaction with friends, relatives, and neighbors. Your knowledge of criminal justice that you have developed in your criminal justice classes is trumped by one experience your friend, relative, or neighbor had with the criminal justice system. They believe they are right because they experienced it. However, there are four errors that occur in the knowledge gained from personal experiences: overgeneralization, selective observation, illogical reasoning, and resistance to change.

Overgeneralization happens when people conclude that what they have observed in one or a few cases is true for all cases. For example, you may see that a wealthy businesswomen in your community is acquitted of bribery and may conclude that “wealthy people, especially women, are never convicted in our criminal justice system,” which is an overgeneralization. It is common to draw conclusions about people and society from our personal interactions, but, in reality, our experiences are limited because we interact with just a small percentage of people in society.

The same is true for practitioners in the criminal justice system. Practitioners have a tendency to believe that because something was done a particular way in their agency, it is done that way in all agencies. That may not be true. Although there are certainly operational similarities across criminal justice agencies, there are also nuances that exist across the over 50,000 criminal justice agencies in the United States. Believing that just because it was that way in your agency, it must be that way in all agencies leads to overgeneralization.

Selective observation is choosing, either consciously or unconsciously, to pay attention to and remember events that support our personal preferences and beliefs. In fact, with selective observation, we will seek out evidence that confirms what we believe to be true and ignore the events that provide contradictory evidence. We are more likely to notice pieces of evidence that reinforce and support our ideology. As applied to the criminal justice system, when we are inclined to be critical of the criminal justice system, it is pretty easy to notice its every failing and ignore its successes. For example, if someone believes the police commonly use excessive force, the person is more likely to pay attention to and remember a police brutality allegation on the nightly news than a police pursuit that led to the apprehension of the suspect without incident on the same nightly news. As another example, if you believe treatment efforts on sex offenders are futile, you will pay attention to and remember each sex offender you hear about that recidivates but will pay little attention to any successes. It is easy to find instances that confirm our beliefs, but with selective observation, the complete picture is not being viewed. Therefore, if we only acknowledge the events that confirm our beliefs and ignore those that challenge them, we are falling victim to selective observation.

Besides selective observation, some of our observations may simply be wrong. Consider eyewitness identification. It is a common practice in the criminal justice system, but research has consistently demonstrated inaccuracies in eyewitness identification. The witness feels certain that the person viewed is the person who committed the offense, but sometimes the witness is wrong. Even when our senses of sight, hearing, taste, touch, and smell are fully operational, our minds have to interpret what we have sensed, which may lead to an inaccurate observation.

RESEARCH IN THE NEWS

When Your Criminal Past Isn’t Yours 16

The business of background checks on prospective employees is increasing significantly. According to the Society for Human Resource Management, since the events of September 11, 2001, the percentage of companies that conduct criminal history checks during the hiring process has risen past 90%. Employers spend at least $2 billion a year to look into the pasts of their prospective employees. Problems with the business of background checks were identified through research that included a review of thousands of pages of court filings and interviews with dozens of court officials, data providers, lawyers, victims, and regulators.

The business of background checks is a system weakened by the conversion to digital files and compromised by the significant number of private companies that profit by amassing public records and selling them to employers. The private companies create a system in which a computer program scrapes the public files of court systems around the country to retrieve personal data. Basically, these are automated data-mining programs. Today, half the courts in the United States put criminal records on their public websites. So, the data are there for the taking, but the records that are retrieved typically are not checked for errors—errors that would be obvious to human eyes.

The errors can start with a mistake entered into the logs of a law enforcement agency or a court file. The biggest culprits, though, are companies that compile databases using public information. In some instances, their automated formulas misinterpret the information provided them. Other times, records wind up assigned to the wrong people with a common name. Furthermore, when a government agency erases a criminal conviction after a designated period of good behavior, many of the commercial databases don’t perform the updates required to purge offenses that have been removed from public record. It is clear that these errors can have substantial ramifications, including damaged reputations and loss of job opportunities.

Illogical reasoning occurs when someone jumps to premature conclusions or presents an argument that is based on invalid assumptions. Premature conclusions occur when we feel we have the answer based on a few pieces of evidence and do not need to seek additional information that may invalidate our conclusion. Think of a detective who, after examining only a few pieces of evidence, quickly narrows in on a murder suspect. It is common for a detective to assess the initial evidence and make an initial determination of who committed the murder. However, it is hoped that the detective will continue to sort through all the evidence for confirmation or rejection of his original conclusion regarding the murder suspect. Illogical reasoning by jumping to premature conclusions is common in everyday life. We look for evidence to confirm or reject our beliefs and stop when a small amount of evidence is present; we jump to conclusions. If a person states, “I know four people who have dropped out of high school, and each one of them ended up addicted to drugs, so all dropouts abuse drugs,” the person is jumping to conclusions.

Illogical reasoning also occurs when an argument, based on invalid assumptions, is presented. Let’s revisit the Scared Straight example previously discussed. Program developers assumed that brief exposure to the harsh realities of prison would deter juveniles from future delinquency. The Scared Straight program is an example of illogical reasoning. Four hours of exposure to prison life is not going to counteract years of delinquency and turn a delinquent into a nondelinquent. The program is based on a false assumption and fails to recognize the substantial risk factors present in the lives of most delinquents that must be mediated before the juvenile can live a crime-free lifestyle. A fear of prison, developed through brief exposure, is not enough to counteract the risk factors present in the lives of most delinquents. Although the Scared Straight program sounds good, it is illogical to assume that a brief experience with prison life will have a stronger impact on the decisions made by delinquents than peer support for delinquency, drug abuse, lack of education, poor parental supervision, and other factors that influence delinquency.

Resistance to change is the reluctance to change our beliefs in light of new, accurate, and valid information to the contrary. Resistance to change is common and it occurs for several reasons. First, even though our personal experience may be counter to our belief system, it is hard to admit we were wrong after we have taken a position on an issue. Even when the research evidence shows otherwise, people who work within programs may still believe they are effective. As previously stated, even though the research evidence shows otherwise, Scared Straight programs still exist and there is even a television show devoted to the program. Second, too much devotion to tradition and the argument that this is the way it has always been done inhibits change and hinders our ability to accept new directions and develop new knowledge. Third, uncritical agreement with authority inhibits change. Although authority knowledge is certainly an important means of gaining knowledge, we must critically evaluate the ideas, beliefs, and statements of those in positions of authority and be willing to challenge those statements where necessary. However, people often accept the beliefs of those in positions of authority without question, which hinders change.

Knowledge from Media Portrayals

Television shows, movies, websites, newspapers, and magazine articles are important sources of information. This is especially true for information about crime and the criminal justice system since most people have not had much contact with criminals or the criminal justice system. Instead of gaining knowledge about the criminal justice system through personal experience, most people learn about crime and the operations of the criminal justice system through media outlets. Since the primary goal of many of these media outlets is to entertain, they may not accurately reflect the reality of crime and criminal justice. Despite their inaccuracies, the media has a substantial impact on what people know about crime and the criminal justice system. Most people know what they know about crime and criminal justice through the media, and this knowledge even has an impact on criminal justice system operations.

An example of the potential impact of the media on the actual operations of the criminal justice system involves the CSI: Crime Scene Investigation television shows. The shows have been criticized for their unrealistic portrayal of the role of forensic science in solving criminal cases. Critics claim that CSI viewers accept what they see on the show as an accurate representation of how forensic science works. When summoned for jury duty, they bring with them unrealistic expectations of the forensic evidence they will see in trial. When the expected sophisticated forensic evidence is not presented in the real trial, the juror is more likely to vote to acquit the defendant. This phenomenon is known as the CSI Effect. Has the research shown that the CSI Effect exists and is impacting the criminal justice system? Most of the research shows that the CSI Effect does not exist and thus does not impact juror decision-making, but other research has shown that viewers of CSI have higher expectations related to evidence presented at trial. 17

There are several instances in which media attention on a particular topic created the idea that a major problem existed when it did not. An example is Halloween sadism. Halloween sadism is the practice of giving contaminated treats to children during trick or treating. 18 In 1985, Joel Best wrote an article entitled, “The Myth of the Halloween Sadist.” 19 His article reviewed press coverage of Halloween sadism in the leading papers in the three largest metropolitan areas ( New York Times, Los Angeles Times, and Chicago Tribune ) from 1958–1984. Although the belief in Halloween sadism is widespread, Best found few reported incidents and few reports of children being injured by Halloween sadism. Follow-ups on these reported incidents led to the conclusion that most of these reports were hoaxes. Best concluded, “I have been unable to find a substantiated report of a child being killed or seriously injured by a contaminated treat picked up in the course of trick or treating.” 20 Since 1985, Best has kept his research up to date and has come to the same conclusion. Halloween sadism is an urban legend; it is a story that is told as true, even though there is little or no evidence that the events in the story ever occurred.

Dispelling Myths: The Power of Research Methods

In the prior section, sources of knowledge were discussed along with the limitations of each. A researcher (e.g., criminologist), ideally, takes no knowledge claim for granted, but instead relies on research methods to discover the truth. In the attempt to generate new knowledge, a researcher is skeptical of knowledge that is generated by the sources discussed in the prior section, and this skepticism leads to the questioning of conventional thinking. Through this process, existing knowledge claims are discredited, modified, or substantiated. Research methods provide the researcher with the tools necessary to test current knowledge and discover new knowledge.

Although knowledge developed through research methods is by no means perfect and infallible, it is definitely a more systematic, structured, precise, and evidence-based process than the knowledge sources previously discussed. However, researchers should not dismiss all knowledge from the prior sources discussed, because, as mentioned, these sources of knowledge are sometimes accurate and certainly have their place in the development of knowledge. Researchers should guard against an elitist mind-set in which all knowledge, unless it is research-based knowledge, is dismissed.

To further discuss the importance of research methods in the development of knowledge, this section will discuss myths about crime and criminal justice. Myths are beliefs that are based on emotion rather than rigorous analysis. Take the myth of the Halloween sadist previously discussed. Many believe that there are real examples of children being harmed by razor blades, poison, or other nefarious objects placed in Halloween candy. This belief has changed the practices of many parents on Halloween; not allowing their children to trick-or-treat in their neighborhood and forbidding them from going to the doors of strangers. After careful analysis by Best, there is not a single, known example of children being seriously injured or killed by contaminated candy given by strangers. The Halloween sadist is a myth but it is still perpetuated today, and as the definition states, it is a belief based upon emotion rather than rigorous analysis. People accept myths as accurate knowledge of reality when, in fact, the knowledge is false.

The power of research is the ability to dispel myths. If someone were to assess the research literature on a myth or do their own research, she would find that the knowledge based on the myth is wrong. Perceived reality is contradicted by the facts developed through research. But that does not mean that the myth still doesn’t exist. It is important to keep in mind that the perpetuation and acceptance of myths by the public, politicians, and criminal justice personnel has contributed to the failure of criminal justice practices and policies designed to reduce crime and improve the operations of the criminal justice system. In this section, a detailed example of a myth about crime, police, courts, and corrections will be presented to demonstrate how the myth has been dispelled through research. In addition, several additional myths about crime, police, courts, and corrections will be briefly presented.

The Health Benefits of Alcohol Consumption 21

The press release from Oregon State University is titled “Beer Compound Shows Potent Promise in Prostate Cancer Battle.” The press release leads to several newspaper articles throughout the country written on the preventative nature of drinking beer on prostate cancer development with titles such as “Beer Protects Your Prostate” and “Beer May Help Men Ward Off Prostate Cancer.” By the titles alone, this sounds great; one of the main ingredients in beer appears to thwart prostate cancer.

The study that generated these headlines was conducted by a group of researchers at Oregon State University using cultured cells with purified compounds in a laboratory setting. The research showed that xanthohumol, a compound found in hops, slowed the growth of prostate cancer cells and also the growth of cells that cause enlarged prostates. But you would have to drink more than 17 pints of beer to consume a medically effective dose of xanthohumol, which is almost a case of beer. In addition, although the research is promising, further study is necessary to determine xanthohumol’s true impact on prostate cancer.

These are the types of headlines that people pay attention to and want to believe as true, even if disproven by later research. People want to believe that there are health benefits to alcohol consumption. You have probably heard about the health benefits of drinking red wine, but here is something you should consider. Recently, the University of Connecticut released a statement describing an extensive research misconduct investigation involving a member of its faculty. The investigation was sparked by an anonymous allegation of research irregularities. The comprehensive report of the investigation, which totals approximately 60,000 pages, concludes that the professor is guilty of 145 counts of fabrication and falsification of data. The professor had gained international notoriety for his research into the beneficial properties of resveratrol, which is found in red wine, especially its impact on aging. Obviously, this throws his research conclusions, that red wine has a beneficial impact on the aging process, into question.

Myths about Crime—Drug Users Are Violent

The myth of drug users as violent offenders continues to be perpetuated by media accounts of violent drug users. The public sees drug users as violent offenders who commit violent crimes to get money for drugs or who commit violent crimes while under the intoxicating properties of drugs. The public also recognizes the violent nature of the drug business with gangs and cartels using violence to protect their turf. In May 2012, extensive media attention was given to the case of the Miami man who ate the face of a homeless man for an agonizing 18 minutes until police shot and killed the suspect. The police believed that the suspect was high on the street drug known as “bath salts.” This horrific case definitely leaves the image in the public’s mind about the relationship between violence and drug use.

In recent years, media reports have focused on the relationship between methamphetamine use and violence; before then it was crack cocaine use and violence. 32 However, media portrayals regarding the violent tendencies of drug users date back to the 1930s and the release of Reefer Madness. In 1985, Goldstein suggested that drugs and violence could be related in three different ways:

1. violence could be the direct result of drug ingestion;

2. violence could be a product of the instability of drug market activity; and

3. violence could be the consequence of people having a compulsive need for drugs or money for drugs. 33

So, what does the research show? Studies have found that homicides related to crack cocaine were usually the product of the instability of drug market activity (i.e., buying and selling drugs can be a violent activity) and rarely the result of drug ingestion. 34 After an extensive review of research studies on alcohol, drugs, and violence, Parker and Auerhahn concluded, “Despite a number of published statements to the contrary, we find no significant evidence suggesting that drug use is associated with violence. There is substantial evidence to suggest that alcohol use is significantly associated with violence of all kinds.” 35 The reality is not everyone who uses drugs becomes violent and users who do become violent do not do so every time they use drugs; therefore, the relationship between violence and drug use is a myth.

MYTHS ABOUT CRIME

Some additional myths about crime that research does not support include:

•Crime statistics accurately show what crimes are being committed and what crimes are most harmful. 22

•Most criminals—especially the dangerous ones—are mentally ill. 23

•White-collar crime is only about financial loss and does not hurt anyone. 24

•Serial murderers are middle-aged, white males. 25

•Criminals are significantly different from noncriminals. 26

•People are more likely to be a victim of violent crime committed by a stranger than by someone they know. 27

•Older adults are more likely to be victimized than people in any other age group. 28

•Sex offender registration protects the public from sexual predators. 29

•Juvenile crime rates are significantly increasing. 30

•Only the most violent juveniles are tried as adults. 31

Myths about Police—Female Police Officers Do Not Perform as Well as Males

Female police officers still face the myth that they cannot perform as well as male police officers. Throughout history, females have faced significant difficulties even becoming police officers. In the past, it was common for police agencies to require all police applicants to meet a minimum height requirement to be considered for employment. The minimum height requirement was 5′8″ for most agencies, which limited the ability of females to successfully meet the minimum standards to become a police officer. Even if women could meet the minimum height requirements, they were typically faced with a physical-abilities test that emphasized upper body strength (e.g., push-ups and bench presses). Women failed these tests more often than men, and thus were not eligible to be police officers. Minimum height requirements are no longer used in law enforcement, but the perception that female police officers are not as good as males still exists. Today, the myth that women cannot be effective police officers is based largely on the belief that the need to demonstrate superior physical strength is a daily, common occurrence in law enforcement along with the belief that police work is routinely dangerous, violent, and crime-related.

So, what does the research show? On occasion, it is useful for police officers to be able to overpower suspects by demonstrating superior physical strength, but those types of activities are rare in law enforcement. In addition, it is fairly rare for a police officer to have to deal with a dangerous and violent encounter or even an incident involving a crime. The Police Services Study conducted in the 1970s analyzed 26,418 calls for service in three metropolitan areas and found that only 19% of calls for service involve crime and only 2% of the total calls for service involve violent crime. 43 This research study was among the first to assess the types of calls for service received by police agencies.

Despite the belief that women do not make good police officers, consistent research findings show that women are extremely capable as police officers, and in some respects, outperform their male counterparts. 44 Research has demonstrated several advantages to the hiring, retention, and promotion of women in law enforcement. First, female officers are as competent as their male counterparts. Research does not show any consistent differences in how male and female patrol officers perform their duties. Second, female officers are less likely to use excessive force. Research has shown that female patrol officers are less likely to be involved in high-speed pursuits, incidents of deadly force, and the use of excessive force. Female officers are more capable at calming potentially violent situations through communication and also demonstrate heightened levels of caution. Third, female officers can help implement community-oriented policing. Studies have shown that female officers are more supportive of the community-policing philosophy than are their male counterparts. Fourth, female officers can improve law enforcement’s response to violence against women. Studies have shown that female officers are more patient and understanding in handling domestic violence calls, and female victims of domestic violence are more likely to provide positive evaluations of female officers than their male counterparts. 52

MYTHS ABOUT POLICE

Some additional myths about the police that research does not support include:

•Police target minorities for traffic stops and arrests. 36

•Most crimes are solved through forensic science. 37

•COMPSTAT reduces crime. 38

•Intensive law enforcement efforts at the street level will lead to the control of illicit drug use and abuse. 39

•Police work primarily entails responding to crimes in progress or crimes that have just occurred. 40

•Police presence reduces crime. 41

•Detectives are most responsible for solving crimes and arresting offenders. 42

Myths about Courts—The Death Penalty Is Administered Fairly

According to a recent Gallup poll, 52% of Americans say the death penalty is applied fairly in the United States, the lowest mark in almost 40 years. 53 The issue of fairness and the death penalty typically concerns whether the punishment is equally imposed on offenders who are equally deserving based on legal factors (i.e., similar offense, similar prior criminal history, similar aggravating circumstances, and similar mitigating circumstances). 54 Unfairness can be shown if similarly situated offenders are more or less likely to receive death sentences based on age, gender, and race.

So, what does the research show? First, has research shown that a defendant’s age influences his or her chances of being sentenced to death? A study of about 5,000 homicides, controlling for legally relevant variables, found that defendants over the age of 25 were more than twice as likely to receive the death penalty in comparison to those 25 years of age or younger. 55

Second, has research shown that a defendant’s gender influences his or her chance of being sentenced to death? Capital punishment is almost exclusively reserved for male defendants. On December 31, 2010, there were 3,158 prisoners under a sentence of death in the United States: 58 were women, or 1.8%. 56 However, women account for 10–12% of all murders in the United States. 57 One research study found that male defendants were 2.6 times more likely than females to receive a death sentence after controlling for legally relevant factors. 58

Third, has research shown that a defendant’s race influences his or her chance of being sentenced to death? Most of the research on the biased nature of the death penalty has focused on racial inequities in the sentence. Although some research has shown that a defendant’s race has an impact on the likelihood of receiving a death sentence, a significant amount of research has shown that the race of the victim has the most substantial impact on death sentences. The research evidence clearly shows that offenders who murder white victims are more likely to receive a death sentence than offenders who murder black victims. 59 When assessing the race of both the victim and offender, the composition most likely to receive the death penalty is when a black offender murders a white victim. 60

MYTHS ABOUT COURTS

Some additional myths about courts that research does not support include:

•Many criminals escape justice because of the exclusionary rule. 45

•Subjecting juvenile offenders to harsh punishments can reduce crime committed by juveniles. 46

•Public opinion is overwhelmingly in favor of imprisonment and harsh punishment for offenders. 47

•The death penalty brings closure and a sense of justice to the family and friends of murder victims. 48

•Insanity is a common verdict in criminal courts in the United States. 49

•Eyewitness identification is reliable evidence. 50

•Most people who commit crimes based on hatred, bias, or discrimination face hate crime charges and longer sentencing. 51

Myths about Corrections—Imprisonment Is the Most Severe Form of Punishment

It seems clear that besides the death penalty, the most severe punishment available in our criminal justice system is to lock up offenders in prison. On a continuum, it is perceived that sentence severity increases as one moves from fines, to probation, to intermediate sanctions such as boot camps, and finally, to incarceration in prison. The public and politicians support this perception as well.

So, what does the research show? What do criminals think is the most severe form of punishment? A growing body of research has assessed how convicted offenders perceive and experience the severity of sentences in our criminal justice system. 61 Research suggests that alternatives to incarceration in prison (i.e., probation and intermediate sanctions) are perceived by many offenders as more severe due to a greater risk of program failure (e.g., probation revocation). In comparison, serving prison time is easier. 62

For example, one study found that about one-third of nonviolent offenders given the option of participating in an Intensive Supervision Probation (ISP) program, chose prison instead because the prospects of working every day and submitting to random drug tests was more punitive than serving time in prison. 73 Prisoners also stated that they would likely be caught violating probation conditions (i.e., high risk of program failure) and be sent to prison anyway. 74 In another research study involving survey responses from 415 inmates serving a brief prison sentence for a nonviolent crime, prison was considered the eighth most severe sanction, with only community service and probation seen as less punitive. Electronic monitoring (seventh), intensive supervision probation (sixth), halfway house (fifth), intermittent incarceration (fourth), day reporting (third), county jail (second), and boot camp (first) were all rated by inmates as more severe sanctions than prison. 75

MYTHS ABOUT CORRECTIONS

Some additional myths about corrections that research does not support include:

•Punishing criminals reduces crime. 63

•Prisons are too lenient in their day-to-day operations (prisons as country clubs). 64

•Prisons can be self-supporting if only prisoners were forced to work. 65

•Private prisons are more cost effective than state-run prisons. 66

•Focus of community corrections is rehabilitation rather than punishment. 67

•Correctional rehabilitation does not work. 68

•Drug offenders are treated leniently by the criminal justice system. 69

•Most death row inmates will be executed eventually. 70

•If correctional sanctions are severe enough, people will think twice about committing crimes. 71

•Sexual violence against and exploitation of inmates of the same gender are primarily the result of lack of heterosexual opportunities. 72

What is Research and Why is It Important to be an Informed Consumer of Research?

We probably should have started the chapter with the question “What is research?” but we wanted to initially lay a foundation for the question with a discussion of the problems with how knowledge is developed and the power of research in discovering the truth. Research methods are tools that allow criminology and criminal justice researchers to systematically study crime and the criminal justice system. The study of research methods is the study of the basic rules, appropriate techniques, and relevant procedures for conducting research. Research methods provide the tools necessary to approach issues in criminal justice from a rigorous standpoint and challenge opinions based solely on nonscientific observations and experiences. Similarly, research is the scientific investigation of an issue, problem, or subject utilizing research methods. Research is a means of knowledge development that is designed to assist in discovering answers to research questions and leads to the creation of new questions.

How Is Knowledge Development through Research Different?

Previously, sources of knowledge development were discussed, including authority, tradition, common sense, personal experience, and media portrayals. The problems generated by each knowledge source were also discussed. Research is another source of knowledge development, but it is different than those previously discussed in several ways. First, research relies on logical and systematic methods and observations to answer questions. Researchers use systematic, well-established research practices to seek answers to their questions. The methods and observations are completed in such a way that others can inspect and assess the methods and observations and offer feedback and criticism. Researchers develop, refine, and report their understanding of crime and the criminal justice system more systematically than the public does through casual observation. Those who conduct scientific research employ much more rigorous methods to gather the information/knowledge they are seeking.

Second, in order to prove that a research finding is correct, a researcher must be able to replicate the finding using the same methods. Only through replication can we have confidence in our original finding. For researchers, it may be important to replicate findings many times over so that we are assured our original finding was not a coincidence or chance occurrence. The Minneapolis Domestic Violence Experiment is an example of this and will be discussed in detail in Chapter 5. In the experiment, the researchers found that arrests for domestic violence lead to fewer repeat incidences in comparison to separation of the people involved and mediation. Five replication studies were conducted and none were able to replicate the findings in the Minneapolis study. In fact, three of the replications found that those arrested for domestic violence had higher levels of continued domestic violence, so arrest did not have the deterrent effect found in the Minneapolis study.

Third, research is objective. Objectivity indicates a neutral and nonbiased perspective when conducting research. Although there are examples to the contrary, the researcher should not have a vested interest in what findings are discovered from the research. The researcher is expected to remain objective and report the findings of the study regardless of whether the findings support their personal opinion or agenda. In addition, research ensures objectivity by allowing others to examine and be critical of the methodology, findings, and results of research studies.

It should be clear that using research methods to answer questions about crime and the criminal justice system will greatly reduce the errors in the development of knowledge previously discussed. For example, research methods reduces the likelihood of overgeneralization by using systematic procedures for selecting individuals or groups to study that are representative of the individuals or groups that we wish to generalize. This is the topic of Chapter 3, which covers sampling procedures. In addition, research methods reduces the risk of selective observation by requiring that we measure and observe our research subjects systematically.

Being an Informed Consumer of Research

Criminal justice and criminological research is important for several reasons. First, it can provide better and more objective information. Second, it can promote better decision-making. Today, more than ever, we live in a world driven by data and in which there is an increasing dependence on the assessment of data when making decisions. As well as possible, research ensures that our decisions are based on data and not on an arbitrary or personal basis. Third, it allows for the objective assessment of programs. Fourth, it has often been the source of innovation within criminal justice agencies. Fifth, it can be directly relevant to criminal justice practice and have a significant impact on criminal justice operations.

Before we apply research results to practices in the criminal justice system, and before we even accept those research results as reasonable, we need to be able to know whether or not they are worthwhile. In other words, should we believe the results of the study? Research has its own limitations, so we need to evaluate research results and the methods used to produce them, and we do so through critical evaluation. Critical evaluation involves identifying both positive and negative aspects of the research study—both the good and the bad. Critical evaluation involves comparing the methodology used in the research with the standards established in research methods.

Through critical evaluation, consumers of research break studies down into their essential elements. What are the research questions and hypotheses? What were the independent and dependent variables? What research design was used? Was probability sampling used? What data-gathering procedures were employed? What type of data analysis was conducted and what conclusions were made? These are some of the questions that are asked by informed consumers of research. The evaluation of research ranges from the manner in which one obtains an idea to the ways in which one writes about the research results, and understanding each step in the research process is useful in our attempts to consume research conducted by others. Located between these two activities are issues concerning ethics, sampling, research design, data analyses, and interpretations.

The research design and procedures are typically the most critically evaluated aspects of research and will likewise receive the greatest amount of attention in this text. Informed consumers of research don’t just take the results of a research study at face value because the study is in an academic journal or written by someone with a Ph.D. Instead, informed consumers critically evaluate research. Taking what is learned throughout this text, critical evaluation of research is covered in Chapter 8, and upon completing this text, it is hoped that you will be an informed consumer of research and will put your research knowledge to use throughout your career.

Although many students will never undertake their own research, all will be governed by policies based upon research and exposed to research findings in their chosen professional positions. Most government agencies, including the criminal justice system, as well as private industry, routinely rely on data analysis. Criminal justice students employed with these agencies will be challenged if not prepared for quantitative tasks. Unfortunately, it is not unusual to find students as well as professionals in criminal justice who are unable to fully understand research reports and journal articles in their own field.

Beyond our criminal justice careers, we are all exposed to and use research to help us understand issues and to make personal decisions. For example, we know that cigarette smoking causes lung cancer and has other significant health impacts, so we don’t smoke. Your doctor tells you that your cholesterol is too high and you need to limit your red meat intake because research shows that consumption of red meat raises cholesterol; so, you quit eating red meat. That is why not all the examples in this text are criminal justice research examples. Some come from the medical field while others come from psychology and other disciplines. This is to remind you that you are probably exposed to much more research than you thought on day one of this class.

Overall, knowledge of research methods will allow you to more appropriately consider and consume information that is important to your career in criminal justice. It will help you better understand the process of asking and answering a question systematically and be a better consumer of the kind of information that you really need to be the best criminal justice professional you can. Once familiar with research methods, your anxiety about reviewing technical reports and research findings can be minimized. As discussed in the next section, research methods involve a process and once you understand the process, you can apply your knowledge to any research study, even those in other disciplines.

The Research Process

One of the nice things about studying research methods is it is about learning a process. Research methods can be seen as a sequential process with the first step being followed by the second step, and so on. There are certainly times when the order of the steps may be modified, but researchers typically follow the same process for each research study they complete regardless of the research topic (as depicted in Figure 2.1 in Chapter 2). Very simply, a research problem or question is identified, and a methodology is selected, developed, and implemented to answer the research question. This sequential process is one of the advantages of understanding research methods, because once you understand the process, you can apply that process to any research question that interests you. In addition, research methods are the same across disciplines. So, sampling is the same in business as it is in health education and as it is in criminal justice. Certainly the use of a particular method will be more common in one discipline in comparison to another, but the protocol for implementing the method to complete the research study is the same. For example, field research (discussed in Chapter 6) is used much more frequently in anthropology than in criminal justice. However, the research protocol to implement field research is the same whether you are studying an indigenous Indian tribe in South America in anthropology or a group of heroin users in St. Louis in criminal justice.

Some authors have presented the research process as a wheel or circle, with no specific beginning or end. Typically, the research process begins with the selection of a research problem and the development of research questions or hypotheses (discussed further in Chapter 2). It is common for the results of previous research to generate new research questions and hypotheses for the researcher. This suggests that research is cyclical, a vibrant and continuous process. When a research study answers one question, the result is often the generation of additional questions, which plunges the researcher right back into the research process to complete additional research to answer these new questions.

In this section, a brief overview of the research process will be presented. The chapters that follow address various aspects of the research process, but it is critical that you keep in mind the overall research process as you read this book, which is why is it presented here. Although you will probably not be expected to conduct a research study on your own, it is important for an educated consumer of research to understand the steps in the research process. The steps are presented in chronological order and appear neatly ordered. In practice, the researcher can go back and forth between the steps in the research process.

Step 1: Select a Topic and Conduct a Literature Review

The first step in the research process is typically the identification of a problem or topic that the researcher is interested in studying. Research topics can arise from a wide variety of sources, including the findings of a current study, a question that a criminal justice agency needs to have answered, or the result of intellectual curiosity. Once the researcher has identified a particular problem or topic, the researcher assesses the current state of the literature related to the problem or topic. The researcher will often spend a considerable amount of time in determining what the existing literature has to say about the topic. Has the topic already been studied to the point that the questions in which the researcher is interested have been sufficiently answered? If so, can the researcher approach the subject from a previously unexamined perspective? Many times, research topics have been previously explored but not brought to completion. If this is the case, it is certainly reasonable to examine the topic again. It is even appropriate to replicate a previous study to determine whether the findings reported in the prior research continue to be true in different settings with different participants. This step in the research process is also discussed in Chapter 2.

Step 2: Develop a Research Question

After a topic has been identified and a comprehensive literature review has been completed on the topic, the next step is the development of a research question or questions. The research question marks the beginning of your research study and is critical to the remaining steps in the research process. The research question determines the research plan and methodology that will be employed in the study, the data that will be collected, and the data analysis that will be performed. Basically, the remaining steps in the process are completed in order to answer the research question or questions established in this step. The development of research questions is discussed in more detail in Chapter 2.

Step 3: Develop a Hypothesis

After the research questions have been established, the next step is the formulation of hypotheses, which are statements about the expected relationship between two variables. For example, a hypothesis may state that there is no relationship between heavy metal music preference and violent delinquency. The two variables stated in the hypothesis are music preference and violent delinquency. Hypothesis development is discussed in more detail in Chapter 2.

Step 4: Operationalize Concepts

Operationalization involves the process of giving the concepts in your study a working definition and determining how each concept in your study will be measured. For example, in Step 3, the variables were music preference and violent delinquency. The process of operationalization involves determining how music preference and violent delinquency will be measured. Operationalization is further discussed in Chapter 2.

Step 5: Develop the Research Plan and Methodology

The next step is to develop the methodology that will be employed to answer the research questions and test the hypotheses. The research methodology is the blueprint for the study, which outlines how the research is to be conducted. The research questions will determine the appropriate methodology for the study. The research design selected should be driven by the research questions asked. In other words, the research questions dictate the methods used to answer them. The methodology is basically a research plan on how the research questions will be answered and will detail:

1. What group, subjects, or population will be studied and selected? Sampling will be discussed in Chapter 3.

2 . What research design will be used to collect data to answer the research questions? Various research designs will be covered in Chapters 4–7.

You need to have familiarity with all research designs so that you can become an educated consumer of research. A survey cannot answer all research questions, so knowing a lot about surveys but not other research designs will not serve you well as you assess research studies. There are several common designs used in criminal justice and criminology research. Brief descriptions of several common research designs are presented below, but each is discussed in detail in later chapters.

Survey research is one of the most common research designs employed in criminal justice research. It obtains data directly from research participants by asking them questions and is often conducted through self-administered questionnaires and personal interviews. For example, a professor might have her students complete a survey during class to understand the relationship between drug use and self-esteem. Survey research is discussed in Chapter 4.

Experimental designs are used when researchers are interested in determining whether a program, policy, practice, or intervention is effective. For example, a researcher may use an experimental design to determine if boot camps are effective at reducing juvenile delinquency. Experimental design is discussed in Chapter 5.

Field research involves researchers studying individuals or groups of individuals in their natural environment. The researcher is observing closely or acting as part of the group under study and is able to describe in depth not only the subject’s behaviors, but also consider the motivations that drive those behaviors. For example, if a researcher wanted to learn more about gangs and their activities, he may “hang out” with a gang in order to observe their behavior. Field research is discussed in Chapter 6.

A case study is an in-depth analysis of one or a few illustrative cases. This design allows the story behind an individual, a particular offender, to be told and then information from cases studies can be extrapolated to a larger group. Often these studies require the review and analysis of documents such as police reports and court records and interviews with the offender and others. For example, a researcher may explore the life history of a serial killer to try and understand why the offender killed. Case studies are discussed in Chapter 6.

Secondary data analysis occurs when researchers obtain and reanalyze data that was originally collected for a different purpose. This can include reanalyzing data collected from a prior research study, using criminal justice agency records to answer a research question, or historical research. For example, a researcher using secondary data analysis may analyze inmate files from a nearby prison to understand the relationship between custody level assignment and disciplinary violations inside prison. Secondary data analysis is discussed in Chapter 7.

Content analysis requires the assessment of content contained in mass communication outlets such as newspapers, television, magazines, and the like. In this research design, documents, publications, or presentations are reviewed and analyzed. For example, a researcher utilizing content analysis might review true crime books involving murder to see how the characteristics of the offender and victim in the true crime books match reality as depicted in the FBI’s Supplemental Homicide Reports. Content analysis is discussed in Chapter 7.

Despite the options these designs offer, other research designs are available and will be discussed later in the text. Ultimately, the design used will depend on the nature of the study and the research questions asked.

Step 6: Execute the Research Plan and Collect Data

The next step in the research process is the collection of the data based on the research design developed. For example, if a survey is developed to study the relationship between gang membership and violent delinquency, the distribution and collection of surveys from a group of high school students would occur in this step. Data collection is discussed in several chapters throughout this text.

Step 7: Analyze Data

After the data have been collected, the next phase in the research process involves analyzing the data through various and appropriate statistical techniques. The most common means for data analysis today is through the use of a computer and statistically oriented software. Data analysis and statistics are discussed in Chapter 9.

Step 8: Report Findings, Results, and Limitations

Reporting and interpreting the results of the study make up the final step in the research process. The findings and results of the study can be communicated through reports, journals, books, or computer presentations. At this step, the results are reported and the research questions are answered. In addition, an assessment is made regarding the support or lack of support for the hypotheses tested. It is also at this stage that the researcher can pose additional research questions that may now need to be answered as a result of the research study. In addition, the limitations of the study, as well as the impact those limitations may have on the results of the study, will be described by the researcher. All research has limitations, so it is incumbent on the researcher to identify those limitations for the reader. The process of assessing the quality of research will be discussed in Chapter 8.

Research in Action: Impacting Criminal Justice Operations

Research in the criminal justice system has had significant impacts on its operations. The following sections provide an example of research that has significantly impacted each of the three main components of the criminal justice system: police, courts, and corrections. The purpose of this section is to demonstrate that research has aided the positive development and progression of the criminal justice system.

Police Research Example 76

The efforts of criminal justice researchers in policing have been important and have created the initial and critical foundation necessary for the further development of effective and productive law enforcement. One seminal study asked: How important is it for the police to respond quickly when a citizen calls? The importance of rapid response was conveyed in a 1973 National Commission on Productivity Report despite the fact that there was very little empirical evidence upon which to base this assumption. In fact, the Commission stated “there is no definitive relationship between response time and deterrence, but professional judgment and logic do suggest that the two are related in a strong enough manner to make more rapid response important.” 77 Basically the Commission members were stating that we don’t have any research evidence that response times are important, but we “know” that they are. Police departments allocated substantial resources to the patrol function and deployed officers in an effort to improve response time through the use of the 9-1-1 telephone number, computer-assisted dispatch, and beat assignment systems. Officers were typically assigned to a patrol beat. When the officers were not answering calls for service, they remained in their assigned beats so they could immediately respond to an emergency.

The data for the project were collected as part of a larger experiment on preventive patrol carried out in Kansas City, Missouri, between October 1972 and September 1973. 78 To determine the impact of response time, researchers speculated that the following variables would be influenced by response time: 1) the outcome of the response, 2) citizen satisfaction with response time, and 3) citizen satisfaction with the responding officer. Several data sources were used in the study. First, surveys were completed after all citizen-initiated calls (excluding automobile accidents) that involved contact with a police officer. The survey instrument consisted of questions to assess the length of time to respond to a call and the outcome of the call (i.e., arrest). Over 1,100 surveys were completed. Second, a follow-up survey was mailed to citizens whom the police had contacted during their response. These surveys asked questions to assess citizen satisfaction with response time and outcome. Over 425 of these surveys were returned.

The data collected during the study showed that response time did not determine whether or not the police made an arrest or recovered stolen property. This was the most surprising finding from the study because it challenged one of the basic underlying principles of police patrol. Researchers attributed the lack of significance to the fact that most citizens waited before calling the police. Rapid response simply did not matter in situations where citizens delayed in reporting the crime.

Rapid response time was not only believed to be important in determining the outcome of a response (i.e., more likely to lead to an arrest), it was also considered an important predictor of citizen satisfaction. Data from the study showed that when the police arrived sooner than expected, citizens were more satisfied with response time. However, subsequent research has shown that citizens are also satisfied with a delayed response as long as the dispatcher sets a reasonable expectation for when the patrol officer will arrive. Response time was also the best predictor of how satisfied a citizen was with the responding officer. It was further revealed that citizens became dissatisfied with the police when they were not informed of the outcome (i.e., someone was arrested). Again, these findings indicate the need for dispatchers and patrol officers to communicate with complainants regarding when they should expect an officer to arrive and the outcome of the call.

Based on the results of the response time study, the researchers concluded that rapid response was not as important as police administrators had thought. Response time was not related to an officer’s ability to make an arrest or recover stolen property. Results from the response time study challenged traditional beliefs about the allocation of patrol in our communities. Based on tradition knowledge, as previously discussed, rapidly responding to calls for service is what the police had always done since they started using patrol vehicles. In addition, common sense, as previously discussed, played a role in the practice of rapid response to calls for service; it just made sense that if a patrol officer arrives sooner, she will be more likely to make an arrest.

Prior to the research, police departments operated under the assumption that rapid response was a crucial factor in the ability of an officer to solve a crime and an important predictor of citizen satisfaction. In response to the research on rapid response, many police departments changed the way they responded to calls for service. Many departments adopted a differential police response approach. Differential police response protocols allow police departments to prioritize calls and rapidly dispatch an officer only when an immediate response is needed (i.e., crimes in progress). For crimes in progress, rapid response is critical and may reduce the injuries sustained by the victim as well, but these emergency calls usually account for less than 2% of all 9-1-1 calls for police service. For nonemergency calls, an officer is either dispatched at a later time when the officer is available or a report is taken over the phone or through some other means. Differential police response has been shown to save departments money and give patrol officers more time to engage in community-oriented and proactive policing activities. The benefits for a department are not at the expense of the public. In fact, a study by Robert Worden found a high degree of citizen satisfaction with differential police response. 79

Courts Research Example 80

Research on the courts component of the criminal justice system, while far from complete, has produced direct effects on the operations of the criminal justice system. The study reviewed in this section asked the following research question: Are jurors able to understand different legal rules for establishing a defendant’s criminal responsibility? The study described below explored the issue of criminal responsibility as it applies to the insanity defense in the United States. For several years, the M ’ Naghten rule was the legal rule applied in all courts of the United States. Under M ’ Naghten, criminal responsibility was absent when the offender did not understand the nature of his actions due to failure to distinguish “right” from “wrong.” This is known as the “right/wrong test” for criminal responsibility. The case of Durham v. United States was heard in the U.S. Court of Appeals for the District of Columbia and offered an alternative test for criminal responsibility and insanity. The legal rule emerging from Durham was that criminal responsibility was absent if the offense was a product of mental disease or defect. This ruling provided psychiatrists with a more important role at trial because of the requirement that the behavior be linked to a mental disorder that only a psychiatrist could officially determine.

At the time of Simon’s 1967 study, most courts across the country still followed the M ’ Naghten rule. Questions arose, however, regarding whether juries differed in their understanding of M ’ Naghten versus Durham and, in turn, whether this resulted in differences in their ability to make informed decisions regarding criminal responsibility in cases involving the insanity defense. The study was designed to determine the effect of different legal rules on jurors’ decision-making in cases where the defense was insanity. There was a question of whether there was a difference between the rules to the extent that jurors understood each rule and could capably apply it.

Simon conducted an experimental study on jury deliberations in cases where the only defense was insanity. 81 Utilizing a mock jury approach, Simon took the transcripts of two actual trials with one reflecting the use of the M ’ Naghten rule and the other the Durham rule. Both cases were renamed and the transcripts were edited to constitute a trial of 60–90 minutes in length. These edited transcripts were then recorded, with University of Chicago Law School faculty as the attorneys, judges, and witnesses involved in each case. Groups of 12 jurors listened to each trial with instruction provided at the end regarding the particular rule of law ( M ’ Naghten or Durham) for determining criminal responsibility. Each juror submitted a written statement with his or her initial decision on the case before jury deliberations, and the juries’ final decisions after deliberation were also reported.

Simon found significant differences in the verdicts across the two groups ( M ’ Naghten rule applied and Durham rule applied) even when the case was the same. For the M ’ Naghten version of the case, the psychiatrists stated that the defendant was mentally ill yet knew right from wrong during the crime. These statements/instructions should have led to a guilty verdict on the part of the mock jury. As expected, the M ’ Naghten juries delivered guilty verdicts in 19 of the 20 trials, with one hung jury. For the Durham version of the case, the psychiatrists stated that the crime resulted from the defendant’s mental illness, which should have lead to acquittal. However, the defendant was acquitted in only five of the 26 Durham trials. Twenty-six groups of 12 jurors were exposed to the Durham version of the trial and the case was the same each time. Simon interpreted these results as suggesting that jurors were unambiguous in their interpretations and applications of M ’ Naghten (due to the consistency in guilty verdicts), but they were less clear on the elements of Durham and how to apply it (reflected by the mix of guilty, not guilty, and hung verdicts). 82

After Simon’s study, most states rejected the Durham test. Recall her finding that the Durham rule produced inconsistent verdicts. She interpreted this finding as Durham being no better than providing no guidance to jurors on how to decide the issue of insanity. The observation helped to fuel arguments against the use of Durham, which, in turn, contributed to its demise as a legal rule. Today, only New Hampshire uses a version of the Durham rule in insanity cases.

WHAT RESEARCH SHOWS: IMPACTING CRIMINAL JUSTICE OPERATIONS

The Punishment Cost of Being Young, Black, and Male

Steffensmeier, Ulmer, and Kramer 83 hypothesized that African Americans overall were not likely to be treated more harshly than white defendants by the courts because it was only particular subgroups of minority defendants that fit with court actors’ stereotypes of “more dangerous” offenders. In particular, they argued that younger African American males not only fulfilled this stereotype more than any other age, race, and gender combination, they were also more likely to be perceived by judges as being able to handle incarceration better than other subgroups.

In order to test their hypotheses, the researchers examined sentencing data from Pennsylvania spanning four years (1989–1992). Almost 139,000 cases were examined. The sentences they examined included whether a convicted defendant was incarcerated in prison or jail, and the length of incarceration in prison or jail. The researchers found that offense severity and prior record were the most important predictors of whether a convicted defendant was incarcerated and the length of incarceration. The authors found that the highest likelihood of incarceration and the longest sentences for males were distributed to African Americans aged 18–29 years. Their analysis of females revealed that white females were much less likely than African American females to be incarcerated, regardless of the age group examined. Taken altogether, the analysis revealed that African American males aged 18–29 years maintained the highest odds of incarceration and the longest sentences relative to any other race, sex, and age group.

Overall, this research showed that judges focused primarily on legal factors (offense severity and prior record) when determining the sentences of convicted offenders. These are the factors we expect judges to consider when making sentencing decisions. However, the research also found that judges base their decisions in part on extralegal factors, particularly the interaction of a defendant’s age, race, and gender. This research expanded our knowledge beyond the impact of singular factors on sentencing to expose the interaction effects of several variables (race, gender, and age). Court personnel are aware of these interaction effects based on this study, and others that followed, as well as their personal experiences in the criminal justice system. Identification and recognition of inequities in our justice system (in this case that young, African American males are punished more severely in our justice system) is the first step in mitigating this inequity.

Corrections Research Example 84

Although the research in corrections is far from complete, it has contributed greatly to the development of innovative programs and the professional development of correctional personnel. The contributions of academic and policy-oriented research can be seen across the whole range of correctional functions from pretrial services through probation, institutional corrections, and parole.

Rehabilitation remained the goal of our correctional system until the early 1970s, when the efficacy of rehabilitation was questioned. Violent crime was on the rise, and many politicians placed the blame on the criminal justice system. Some believed the system was too lenient on offenders. Interest in researching the effectiveness of correctional treatment remained low until 1974 when an article written by Robert Martinson and published in Public Interest titled “What Works? Questions and Answers about Prison Reform” generated enormous political and public attention to the effectiveness of correctional treatment. 85

Over a six-month period, Martinson and his colleagues reviewed all of the existing literature on correctional treatment published in English from 1945 to 1967. Each of the articles was evaluated according to traditional standards of social science research. Only studies that utilized an experimental design, included a sufficient sample size, and could be replicated were selected for review. A total of 231 studies examining a variety of different types of treatment were chosen, including educational and vocational training, individual and group counseling, therapeutic milieus, medical treatment, differences in length and type of incarceration, and community corrections. All of the treatment studies included at least one measure of offender recidivism, such as whether or not offenders were rearrested or violated their parole. The recidivism measures were used to examine the success or failure of a program in terms of reducing crime.

After reviewing all 231 studies, Martinson reported that there was no consistent evidence that correctional treatment reduced recidivism. Specifically, he wrote, “with few and isolated exceptions, the rehabilitative efforts that have been reported so far have had no appreciable effect on recidivism.” 86 Martinson further indicated that the lack of empirical support for correctional treatment could be a consequence of poorly implemented programs. If the quality of the programs were improved, the results may have proved more favorable, but this conclusion was for the most part ignored by the media and policy-makers.

Martinson’s report became commonly referred to as “nothing works” and was subsequently used as the definitive study detailing the failures of rehabilitation. The article had implications beyond questioning whether or not specific types of correctional treatment reduced recidivism. The entire philosophy of rehabilitation was now in doubt because of Martinson’s conclusion that “our present strategies … cannot overcome, or even appreciably reduce, the powerful tendencies of offenders to continue in criminal behavior.” 87

Martinson’s article provided policy makers the evidence to justify spending cuts on rehabilitative programs. Furthermore, it allowed politicians to respond to growing concerns about crime with punitive, get-tough strategies. States began implementing strict mandatory sentences that resulted in more criminals being sent to prison and for longer periods of time. Over the next several years, Martinson’s article was used over and over to support abandoning efforts to treat offenders until rehabilitation became virtually nonexistent in our correctional system.

Chapter Summary

This chapter began with a discussion of sources of knowledge development and the problems with each. To depict the importance of research methods in knowledge development, myths about crime and the criminal justice system were reviewed along with research studies that have dispelled myths. As the introductory chapter in this text, this chapter also provided an overview of the steps in the research process from selecting a topic and conducting a literature review at the beginning of a research study to reporting findings, results, and limitations at the end of the study. Examples of actual research studies in the areas of police, courts, and corrections were also provided in this chapter to demonstrate the research process in action and to illustrate how research has significantly impacted practices within the criminal justice system. In addition, this chapter demonstrated the critical importance of becoming an informed consumer of research in both your personal and professional lives.

Critical Thinking Questions

1. What are the primary sources of knowledge development, and what are the problems with each?

2. How is knowledge developed through research methods different from other sources of knowledge?

3. What myths about crime and criminal justice have been dispelled through research? Give an example of a research study that dispelled a myth.

4. Why is it important to be an informed consumer of research?

5. What are the steps in the research process, and what activities occur at each step?

authority knowledge: Knowledge developed when we accept something as being correct and true just because someone in a position of authority says it is true

case study: An in-depth analysis of one or a few illustrative cases

common sense knowledge: Knowledge developed when the information “just makes sense”

content analysis: A method requiring the analyzing of content contained in mass communication outlets such as newspapers, television, magazines, and the like

CSI Effect: Due to the unrealistic portrayal of the role of forensic science in solving criminal cases in television shows, jurors are more likely to vote to acquit a defendant when the expected sophisticated forensic evidence is not presented

differential police response: Methods that allow police departments to prioritize calls and rapidly dispatch an officer only when an immediate response is needed (i.e., crimes in progress)

experimental designs: Used when researchers are interested in determining whether a program, policy, practice, or intervention is effective

field research: Research that involves researchers studying individuals or groups of individuals in their natural environment

Halloween sadism: The practice of giving contaminated treats to children during trick or treating

hypotheses: Statements about the expected relationship between two concepts

illogical reasoning: Occurs when someone jumps to premature conclusions or presents an argument that is based on invalid assumptions

myths: Beliefs that are based on emotion rather than rigorous analysis

operationalization: The process of giving a concept a working definition; determining how each concept in your study will be measured

overgeneralization: Occurs when people conclude that what they have observed in one or a few cases is true for all cases

personal experience knowledge: Knowledge developed through actual experiences

research: The scientific investigation of an issue, problem, or subject utilizing research methods

research methods: The tools that allow criminology and criminal justice researchers to systematically study crime and the criminal justice system and include the basic rules, appropriate techniques, and relevant procedures for conducting research

resistance to change: The reluctance to change our beliefs in light of new, accurate, and valid information to the contrary

secondary data analysis: Occurs when researchers obtain and reanalyze data that were originally collected for a different purpose

selective observation: Choosing, either consciously or unconsciously, to pay attention to and remember events that support our personal preferences and beliefs

survey research: Obtaining data directly from research participants by asking them questions, often conducted through self-administered questionnaires and personal interviews

tradition knowledge: Knowledge developed when we accept something as true because that is the way things have always been, so it must be right

variables: Concepts that have been given a working definition and can take on different values

1 Briggs, Lisa T., Stephen E. Brown, Robert B. Gardner, and Robert L. Davidson. (2009). “D.RA.MA: An extended conceptualization of student anxiety in criminal justice research methods courses.” Journal of Criminal Justice Education 20 (3), 217–226.

2 Betz, N. E. (1978). “Prevalence, distribution, and correlates of math anxiety in college students. Journal of Counseling Psychology 25 (5), 441–448.

3 Briggs, et al., 2009, p. 221.

4 Ibid, p. 221.

5 Ibid, p. 221.

6 Kappeler, Victor E., and Gary W. Potter. (2005). The mythology of crime and criminal justice. Prospect Heights, IL: Waveland.

7 Tennessee v. Gamer, 471 U.S. 1 (1985).

8 Lombroso-Ferrero, Gina. (1911). Criminal man, according to the classification of Cesare Lombroso. New York: Putnam.

9 This study was included in Amy B. Thistlethwaite and John D. Wooldredge. (2010). Forty studies that changed criminal justice: Explorations into the history of criminal justice research. Upper Saddle River, NJ: Prentice Hall.

10 Petersilia, J., S. Turner, J. Kahan, and J. Peterson. (1985). Granting felons probation: Public risks and alternatives. Santa Monica, CA: Rand.

11 Vito, G. (1986). “Felony probation and recidivism: Replication and response.” Federal Probation 50, 17–25.

12 Conrad, J. (1985). “Research and development in corrections.” Federal Probation 49, 69–71.

13 Finckenauer, James O. (1982). Scared straight! and the panacea phenomenon. Englewood Cliffs, NJ: Prentice Hall.

14 Yarborough, J.C. (1979). Evaluation of JOLT (Juvenile Offenders Learn Truth) as a deterrence program. Lansing, MI: Michigan Department of Corrections.

15 Petrosino, Anthony, Carolyn Turpin-Petrosino, and James O. Finckenauer. (2000). “Well-meaning programs can have harmful effects! Lessons from experiments of programs such as Scared Straight,” Crime & Delinquency 46, 354–379.

16 Robertson, Jordan. “I’m being punished for living right”: Background check system is haunted by errors. December 20, 2011. http://finance.yahoo.com/news /ap-impact-criminal-past-isnt-182335059.html. Retrieved on December 29, 2011.

17 Shelton, D. E. (2008). “The ‘CSI Effect’: Does it really exist?” NIJ Journal 259 [NCJ 221501].

18 Best, Joel. (2011). “Halloween sadism: The evidence.” http://dspace.udel.edu:8080/dspace/bitstream/handle/ 19716/726/Halloween%20sadism.revised%20thru%20201l.pdf?sequence=6. Retrieved on May 7, 2012.

19 Best, Joel. (1985, November). “The myth of the Halloween sadist. Psychology Today 19 (11), p. 14.

21 “Beer compound shows potent promise in prostate cancer battle.” Press release from Oregon State University May 30, 2006. http://oregonstate.edu/ua/ncs/archives/2006/ may/beer-compound-shows-potent-promise-prostate-cancer-battle. Retrieved on January 6, 2012; Colgate, Emily C., Cristobal L. Miranda, Jan F. Stevens, Tammy M. Bray, and Emily Ho. (2007). “Xanthohumol, a prenylflavonoid derived from hops induces apoptosis and inhibits NF-kappaB activation in prostate epithelial cells,” Cancer Letters 246, 201–209; “Health benefits of red wine exaggerated” http://health.yahoo.net/articles /nutrition/health-benefits-red-wine-exaggerated. Retrieved on January 14, 2012; “Scientific journals notified following research misconduct investigation.” January 11, 2012. http://today.uconn.edu/blog/2012/01/scientific-journals -notified-following-research-misconduct-investigation/. Retrieved on January 14, 2012.

22 Pepinsky, Hal. “The myth that crime and criminality can be measured.” 3–11 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

23 Bullock, Jennifer L., and Bruce A. Arrigo. “The myth that mental illness causes crime.” 12–19 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

24 Friedrichs, David O. “The myth that white-collar crime is only about financial loss.” 20–28 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

25 Kuhns III, Joseph B., and Charisse T. M. Coston. “The myth that serial murderers are disproportionately white males.” 37–44 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

26 Longmire, Dennis R., Jacqueline Buffington-Vollum, and Scott Vollum. “The myth of positive differentiation in the classification of dangerous offenders.” 123–131 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

27 Masters, Ruth E., Lori Beth Way, Phyllis B. Gerstenfeld, Bernadette T. Muscat, Michael Hooper, John P. J. Dussich, Lester Pincu, and Candice A. Skrapec. (2013). CJ realities and challenges, 2nd ed. New York: McGraw-Hill.

32 Brownstein, Henry H. “The myth of drug users as violent offenders.” 45–53 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

33 Goldstein, P. (1985). “The drugs/violence nexus: A tripartite conceptual framework.” Journal of Drug Issues 15, 493–506.

34 Goldstein, P, H. Brownstein, and P. Ryan. (1992). “Drug-related homicide in New York City: 1984 and 1988.” Crime & Delinquency 38, 459–476.

35 Parker, R., and K. Auerhahn. (1998). “Alcohol, drugs, and violence.” Annual Review of Sociology 24, 291–311, p. 291.

36 Buerger, Michael. “The myth of racial profiling.” 97–103 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

37 Cordner, Gary, and Kathryn E. Scarborough. “The myth that science solves crimes.” 104–110 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

38 Willis, James J., Stephen D. Mastrofski, and David Weisburd. “The myth that COMPSTAT reduces crime and transforms police organizations.” 111–119 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

39 Masters, et al., 2013.

43 Scott, Eric J. (1981). Calls for service: Citizen demand and initial police response. Washington, DC: Government Printing Office.

44 Lersch, Kim. “The myth of policewomen on patrol.” 89–96 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

45 Janikowski, Richard. “The myth that the exclusionary rule allows many criminals to escape justice.” 132–139 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

46 Bishop, Donna M. “The myth that harsh punishments reduce juvenile crime.” 140–148 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

47 Immarigeon, Russ. “The myth that public attitudes are punitive.” 149–157 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

48 Acker, James R. “The myth of closure and capital punishment.” 167–175 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

49 Masters, et al., 2013.

52 Lersch, 2006.

53 Newport, Frank. “In U.S., support for death penalty falls to 39-year low.” October 13, 2011. http://www.gallup .com/poll/150089/support-death-penalty-falls-year-low.aspx. Retrieved on April 16, 2012.

54 Applegate, Brandon. “The myth that the death penalty is administered fairly.” 158–166 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

55 Williams, M. R., and J. E. Holcomb. (2001). “Racial disparity and death sentences in Ohio.” Journal of Criminal Justice 29, 207–218.

56 Snell, Tracy L. (2011, December). Capital punishment, 2010—statistical tables. Washington, DC: Bureau of Justice Statistics.

57 Applegate, 2006.

58 Williams and Holcomb, 2001.

59 Applegate, 2006.

61 Wood, Peter B. “The myth that imprisonment is the most severe form of punishment.” 192–200 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

63 Michalowski, Raymond. “The myth that punishment reduces crime.” 179–191 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

64 McShane, Marilyn, Frank P. Williams III, and Beth Pelz. “The myth of prisons as country clubs.” 201–208 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

65 Parker, Mary. “The myth that prisons can be self-supporting.” 209–213 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

66 Blakely, Curtis, and John Ortiz Smykla. “Correctional privatization and the myth of inherent efficiency.” 214–220 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

67 Jones, G. Mark. “The myth that the focus of community corrections is rehabilitation.” 221–226 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

68 Cullen, Francis T., and Paula Smith. “The myth that correctional rehabilitation does not work.” 227–238 in Bohm, Robert M., and Jeffrey T. Walker. (2006). Demystifying crime and criminal justice. Los Angeles: Roxbury.

69 Masters, et al., 2013.

73 Petersilia, Joan. (1990). “When probation becomes more dreaded than prison. Federal Probation 54, 23–27.

75 Wood, P. B., and H. G. Grasmick. (1999). “Toward the development of punishment equivalencies: Male and female inmates rate the severity of alternative sanctions compared to prison.” Justice Quarterly 16, 19–50.

76 Example is excerpted from Amy B. Thistlethwaite and John D. Wooldredge. (2010). Forty studies that changed criminal justice: Explorations into the history of criminal justice research. Upper Saddle River, NJ: Prentice Hall. This is an excellent book that demonstrates the impact research has had on criminal justice operations.

77 National Commission on Productivity. (1973). Opportunities for improving productivity in police services. Washington, DC: United States Government Printing Office, p. 19.

78 Pate, T., A. Ferrara, R. Bowers, and J. Lorence. (1976). Police response time: Its determinants and effects. Washington, DC: Police Foundation.

79 Worden, R. (1993). “Toward equity and efficiency in law enforcement: Differential police response. American Journal of Police 12, 1–32.

80 Example is excerpted from Amy B. Thistlethwaite and John D. Wooldredge. (2010). Forty studies that changed criminal justice: Explorations into the history of criminal justice research. Upper Saddle River, NJ: Prentice Hall.

81 Simon, R. (1967). The jury and the defense of insanity. Boston: Little, Brown.

83 Steffensmeier, D., J. Ulmer, & J. Kramer. (1998). “The interaction of race, gender, and age in criminal sentencing: The punishment cost of being young, black, and male. Criminology 36, 763–797.

84 Example is excerpted from Amy B. Thistlethwaite and John D. Wooldredge. (2010). Forty studies that changed criminal justice: Explorations into the history of criminal justice research. Upper Saddle River, NJ: Prentice Hall.

85 Martinson, R. (1974). “What works? Questions and answers about prison reform.” The Public Interest 10, 22–54.

86 Ibid, p. 25.

87 Ibid, p. 49.

Applied Research Methods in Criminal Justice and Criminology by University of North Texas is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License , except where otherwise noted.

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Conducting research, the research process.

Step 1: Exploring an idea
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Step 1: Exploring Your Research Idea and Constructing Your Search

If you know you are interested in doing research in a broad subject area, try to think of ways you can make your subject more specific. One way is by stating your topic as a question. For example, if you are interested in writing about sleep disorders you might ask yourself the following question: Can sleep disorders affect academic success in college students? If you don't have enough information to express your topic idea as a specific question, do some background reading first.

Step 2: Finding Background Information

Consult general reference sources, e.g., an encyclopedia, before jumping into more specialized and specific searches. Encyclopedias provide information on key concepts, context, and vocabulary for many different fields. Subject-specific encyclopedias will provide additional information that may lead to ideas for additional search terms.

Step 3: Gathering More Information

Use the search terms/keywords you brainstormed in Step 1: Exploring your Research Idea to search the Classic Catalog . Note where the item is located in the library and the circulation status. When you find a good book, scan the bibliography for additional sources. Look for book-length bibliographies, literature reviews, and annual reviews in your research area; this type of resource lists hundreds of books and articles in one subject area. To find these resources, use your keywords/search terms followed by the word "AND bibliographies" in the Classic Catalog .

Step 4: Locating Current Research

Journal articles are a great resource for learning about cutting-edge research in your area. Indexes and databases allow you to search across many journal publishers at once to find citations, abstracts, and full-text to articles.

Step 5: Evaluating Your Sources

As you search and find citations and/or abstracts for specific books, articles, or websites, consider the following established criteria for evaluating the quality of books, journal articles, and websites.

Step 6: Cite What You Find in Discipline-Appropriate Format

When conducting research, it’s necessary to document sources you use; commonly, this is called citing your sources. Citing your sources is an important part of research and scholarship; it is important to give credit to the ideas of others. In addition, readers of your work may want to find and read some of the sources you used. Different academic disciplines follow different citation styles. Two of the more common citation styles are APA or MLA. Failing to cite properly is plagiarism. For further details on other aspects of plagiarism, consult WU’s Academic Integrity Policy .

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Starting the research process

A Beginner's Guide to Starting the Research Process

When you have to write a thesis or dissertation , it can be hard to know where to begin, but there are some clear steps you can follow.

The research process often begins with a very broad idea for a topic you’d like to know more about. You do some preliminary research to identify a problem . After refining your research questions , you can lay out the foundations of your research design , leading to a proposal that outlines your ideas and plans.

This article takes you through the first steps of the research process, helping you narrow down your ideas and build up a strong foundation for your research project.

Step 1: choose your topic, step 2: identify a problem, step 3: formulate research questions, step 4: create a research design, step 5: write a research proposal, other interesting articles.

First you have to come up with some ideas. Your thesis or dissertation topic can start out very broad. Think about the general area or field you’re interested in—maybe you already have specific research interests based on classes you’ve taken, or maybe you had to consider your topic when applying to graduate school and writing a statement of purpose .

Even if you already have a good sense of your topic, you’ll need to read widely to build background knowledge and begin narrowing down your ideas. Conduct an initial literature review to begin gathering relevant sources. As you read, take notes and try to identify problems, questions, debates, contradictions and gaps. Your aim is to narrow down from a broad area of interest to a specific niche.

Make sure to consider the practicalities: the requirements of your programme, the amount of time you have to complete the research, and how difficult it will be to access sources and data on the topic. Before moving onto the next stage, it’s a good idea to discuss the topic with your thesis supervisor.

>>Read more about narrowing down a research topic

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So you’ve settled on a topic and found a niche—but what exactly will your research investigate, and why does it matter? To give your project focus and purpose, you have to define a research problem .

The problem might be a practical issue—for example, a process or practice that isn’t working well, an area of concern in an organization’s performance, or a difficulty faced by a specific group of people in society.

Alternatively, you might choose to investigate a theoretical problem—for example, an underexplored phenomenon or relationship, a contradiction between different models or theories, or an unresolved debate among scholars.

To put the problem in context and set your objectives, you can write a problem statement . This describes who the problem affects, why research is needed, and how your research project will contribute to solving it.

>>Read more about defining a research problem

Next, based on the problem statement, you need to write one or more research questions . These target exactly what you want to find out. They might focus on describing, comparing, evaluating, or explaining the research problem.

A strong research question should be specific enough that you can answer it thoroughly using appropriate qualitative or quantitative research methods. It should also be complex enough to require in-depth investigation, analysis, and argument. Questions that can be answered with “yes/no” or with easily available facts are not complex enough for a thesis or dissertation.

In some types of research, at this stage you might also have to develop a conceptual framework and testable hypotheses .

>>See research question examples

The research design is a practical framework for answering your research questions. It involves making decisions about the type of data you need, the methods you’ll use to collect and analyze it, and the location and timescale of your research.

There are often many possible paths you can take to answering your questions. The decisions you make will partly be based on your priorities. For example, do you want to determine causes and effects, draw generalizable conclusions, or understand the details of a specific context?

You need to decide whether you will use primary or secondary data and qualitative or quantitative methods . You also need to determine the specific tools, procedures, and materials you’ll use to collect and analyze your data, as well as your criteria for selecting participants or sources.

>>Read more about creating a research design

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what is importance of conducting research

Finally, after completing these steps, you are ready to complete a research proposal . The proposal outlines the context, relevance, purpose, and plan of your research.

As well as outlining the background, problem statement, and research questions, the proposal should also include a literature review that shows how your project will fit into existing work on the topic. The research design section describes your approach and explains exactly what you will do.

You might have to get the proposal approved by your supervisor before you get started, and it will guide the process of writing your thesis or dissertation.

>>Read more about writing a research proposal

If you want to know more about the research process , methodology , research bias , or statistics , make sure to check out some of our other articles with explanations and examples.

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Open access
Published: 12 December 2023

Examining the role of community resilience and social capital on mental health in public health emergency and disaster response: a scoping review

C. E. Hall 1 , 2 ,
H. Wehling 1 ,
J. Stansfield 3 ,
J. South 3 ,
S. K. Brooks 2 ,
N. Greenberg 2 , 4 ,
R. Amlôt 1 &
D. Weston 1

BMC Public Health volume 23 , Article number: 2482 ( 2023 ) Cite this article

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The ability of the public to remain psychologically resilient in the face of public health emergencies and disasters (such as the COVID-19 pandemic) is a key factor in the effectiveness of a national response to such events. Community resilience and social capital are often perceived as beneficial and ensuring that a community is socially and psychologically resilient may aid emergency response and recovery. This review presents a synthesis of literature which answers the following research questions: How are community resilience and social capital quantified in research?; What is the impact of community resilience on mental wellbeing?; What is the impact of infectious disease outbreaks, disasters and emergencies on community resilience and social capital?; and, What types of interventions enhance community resilience and social capital?

A scoping review procedure was followed. Searches were run across Medline, PsycInfo, and EMBASE, with search terms covering both community resilience and social capital, public health emergencies, and mental health. 26 papers met the inclusion criteria.

The majority of retained papers originated in the USA, used a survey methodology to collect data, and involved a natural disaster. There was no common method for measuring community resilience or social capital. The association between community resilience and social capital with mental health was regarded as positive in most cases. However, we found that community resilience, and social capital, were initially negatively impacted by public health emergencies and enhanced by social group activities.

Several key recommendations are proposed based on the outcomes from the review, which include: the need for a standardised and validated approach to measuring both community resilience and social capital; that there should be enhanced effort to improve preparedness to public health emergencies in communities by gauging current levels of community resilience and social capital; that community resilience and social capital should be bolstered if areas are at risk of disasters or public health emergencies; the need to ensure that suitable short-term support is provided to communities with high resilience in the immediate aftermath of a public health emergency or disaster; the importance of conducting robust evaluation of community resilience initiatives deployed during the COVID-19 pandemic.

Peer Review reports

For the general population, public health emergencies and disasters (e.g., natural disasters; infectious disease outbreaks; Chemical, Biological, Radiological or Nuclear incidents) can give rise to a plethora of negative outcomes relating to both health (e.g. increased mental health problems [ 1 , 2 , 3 , 4 ]) and the economy (e.g., increased unemployment and decreased levels of tourism [ 4 , 5 , 6 ]). COVID-19 is a current, and ongoing, example of a public health emergency which has affected over 421 million individuals worldwide [ 7 ]. The long term implications of COVID-19 are not yet known, but there are likely to be repercussions for physical health, mental health, and other non-health related outcomes for a substantial time to come [ 8 , 9 ]. As a result, it is critical to establish methods which may inform approaches to alleviate the longer-term negative consequences that are likely to emerge in the aftermath of both COVID-19 and any future public health emergency.

The definition of resilience often differs within the literature, but ultimately resilience is considered a dynamic process of adaptation. It is related to processes and capabilities at the individual, community and system level that result in good health and social outcomes, in spite of negative events, serious threats and hazards [ 10 ]. Furthermore, Ziglio [ 10 ] refers to four key types of resilience capacity: adaptive, the ability to withstand and adjust to unfavourable conditions and shocks; absorptive, the ability to withstand but also to recover and manage using available assets and skills; anticipatory, the ability to predict and minimize vulnerability; and transformative, transformative change so that systems better cope with new conditions.

There is no one settled definition of community resilience (CR). However, it generally relates to the ability of a community to withstand, adapt and permit growth in adverse circumstances due to social structures, networks and interdependencies within the community [ 11 ]. Social capital (SC) is considered a major determinant of CR [ 12 , 13 ], and reflects strength of a social network, community reciprocity, and trust in people and institutions [ 14 ]. These aspects of community are usually conceptualised primarily as protective factors that enable communities to cope and adapt collectively to threats. SC is often broken down into further categories [ 15 ], for example: cognitive SC (i.e. perceptions of community relations, such as trust, mutual help and attachment) and structural SC (i.e. what actually happens within the community, such as participation, socialising) [ 16 ]; or, bonding SC (i.e. connections among individuals who are emotionally close, and result in bonds to a particular group [ 17 ]) and bridging SC (i.e. acquaintances or individuals loosely connected that span different social groups [ 18 ]). Generally, CR is perceived to be primarily beneficial for multiple reasons (e.g. increased social support [ 18 , 19 ], protection of mental health [ 20 , 21 ]), and strengthening community resilience is a stated health goal of the World Health Organisation [ 22 ] when aiming to alleviate health inequalities and protect wellbeing. This is also reflected by organisations such as Public Health England (now split into the UK Health Security Agency and the Office for Health Improvement and Disparities) [ 23 ] and more recently, CR has been targeted through the endorsement of Community Champions (who are volunteers trained to support and to help improve health and wellbeing. Community Champions also reflect their local communities in terms of population demographics for example age, ethnicity and gender) as part of the COVID-19 response in the UK (e.g. [ 24 , 25 ]).

Despite the vested interest in bolstering communities, the research base establishing: how to understand and measure CR and SC; the effect of CR and SC, both during and following a public health emergency (such as the COVID-19 pandemic); and which types of CR or SC are the most effective to engage, is relatively small. Given the importance of ensuring resilience against, and swift recovery from, public health emergencies, it is critically important to establish and understand the evidence base for these approaches. As a result, the current review sought to answer the following research questions: (1) How are CR and SC quantified in research?; (2) What is the impact of community resilience on mental wellbeing?; (3) What is the impact of infectious disease outbreaks, disasters and emergencies on community resilience and social capital?; and, (4) What types of interventions enhance community resilience and social capital?

By collating research in order to answer these research questions, the authors have been able to propose several key recommendations that could be used to both enhance and evaluate CR and SC effectively to facilitate the long-term recovery from COVID-19, and also to inform the use of CR and SC in any future public health disasters and emergencies.

A scoping review methodology was followed due to the ease of summarising literature on a given topic for policy makers and practitioners [ 26 ], and is detailed in the following sections.

Identification of relevant studies

An initial search strategy was developed by authors CH and DW and included terms which related to: CR and SC, given the absence of a consistent definition of CR, and the link between CR and SC, the review focuses on both CR and SC to identify as much relevant literature as possible (adapted for purpose from Annex 1: [ 27 ], as well as through consultation with review commissioners); public health emergencies and disasters [ 28 , 29 , 30 , 31 ], and psychological wellbeing and recovery (derived a priori from literature). To ensure a focus on both public health and psychological research, the final search was carried across Medline, PsycInfo, and EMBASE using OVID. The final search took place on the 18th of May 2020, the search strategy used for all three databases can be found in Supplementary file 1 .

Selection criteria

The inclusion and exclusion criteria were developed alongside the search strategy. Initially the criteria were relatively inclusive and were subject to iterative development to reflect the authors’ familiarisation with the literature. For example, the decision was taken to exclude research which focused exclusively on social support and did not mention communities as an initial title/abstract search suggested that the majority of this literature did not meet the requirements of our research question.

The full and final inclusion and exclusion criteria used can be found in Supplementary file 2 . In summary, authors decided to focus on the general population (i.e., non-specialist, e.g. non-healthcare worker or government official) to allow the review to remain community focused. The research must also have assessed the impact of CR and/or SC on mental health and wellbeing, resilience, and recovery during and following public health emergencies and infectious disease outbreaks which affect communities (to ensure the research is relevant to the review aims), have conducted primary research, and have a full text available or provided by the first author when contacted.

Charting the data

All papers were first title and abstract screened by CH or DW. Papers then were full text reviewed by CH to ensure each paper met the required eligibility criteria, if unsure about a paper it was also full text reviewed by DW. All papers that were retained post full-text review were subjected to a standardised data extraction procedure. A table was made for the purpose of extracting the following data: title, authors, origin, year of publication, study design, aim, disaster type, sample size and characteristics, variables examined, results, restrictions/limitations, and recommendations. Supplementary file 3 details the charting the data process.

Analytical method

Data was synthesised using a Framework approach [ 32 ], a common method for analysing qualitative research. This method was chosen as it was originally used for large-scale social policy research [ 33 ] as it seeks to identify: what works, for whom, in what conditions, and why [ 34 ]. This approach is also useful for identifying commonalities and differences in qualitative data and potential relationships between different parts of the data [ 33 ]. An a priori framework was established by CH and DW. Extracted data was synthesised in relation to each research question, and the process was iterative to ensure maximum saturation using the available data.

Study selection

The final search strategy yielded 3584 records. Following the removal of duplicates, 2191 records remained and were included in title and abstract screening. A PRISMA flow diagram is presented in Fig. 1 .

PRISMA flow diagram

At the title and abstract screening stage, the process became more iterative as the inclusion criteria were developed and refined. For the first iteration of screening, CH or DW sorted all records into ‘include,’ ‘exclude,’ and ‘unsure’. All ‘unsure’ papers were re-assessed by CH, and a random selection of ~ 20% of these were also assessed by DW. Where there was disagreement between authors the records were retained, and full text screened. The remaining papers were reviewed by CH, and all records were categorised into ‘include’ and ‘exclude’. Following full-text screening, 26 papers were retained for use in the review.

Study characteristics

This section of the review addresses study characteristics of those which met the inclusion criteria, which comprises: date of publication, country of origin, study design, study location, disaster, and variables examined.

Date of publication

Publication dates across the 26 papers spanned from 2008 to 2020 (see Fig. 2 ). The number of papers published was relatively low and consistent across this timescale (i.e. 1–2 per year, except 2010 and 2013 when none were published) up until 2017 where the number of papers peaked at 5. From 2017 to 2020 there were 15 papers published in total. The amount of papers published in recent years suggests a shift in research and interest towards CR and SC in a disaster/ public health emergency context.

Graph to show retained papers date of publication

Country of origin

The locations of the first authors’ institutes at the time of publication were extracted to provide a geographical spread of the retained papers. The majority originated from the USA [ 35 , 36 , 37 , 38 , 39 , 40 , 41 ], followed by China [ 42 , 43 , 44 , 45 , 46 ], Japan [ 47 , 48 , 49 , 50 ], Australia [ 51 , 52 , 53 ], The Netherlands [ 54 , 55 ], New Zealand [ 56 ], Peru [ 57 ], Iran [ 58 ], Austria [ 59 ], and Croatia [ 60 ].

There were multiple methodological approaches carried out across retained papers. The most common formats included surveys or questionnaires [ 36 , 37 , 38 , 42 , 46 , 47 , 48 , 49 , 50 , 53 , 54 , 55 , 57 , 59 ], followed by interviews [ 39 , 40 , 43 , 51 , 52 , 60 ]. Four papers used both surveys and interviews [ 35 , 41 , 45 , 58 ], and two papers conducted data analysis (one using open access data from a Social Survey [ 44 ] and one using a Primary Health Organisations Register [ 56 ]).

Study location

The majority of the studies were carried out in Japan [ 36 , 42 , 44 , 47 , 48 , 49 , 50 ], followed by the USA [ 35 , 37 , 38 , 39 , 40 , 41 ], China [ 43 , 45 , 46 , 53 ], Australia [ 51 , 52 ], and the UK [ 54 , 55 ]. The remaining studies were carried out in Croatia [ 60 ], Peru [ 57 ], Austria [ 59 ], New Zealand [ 56 ] and Iran [ 58 ].

Multiple different types of disaster were researched across the retained papers. Earthquakes were the most common type of disaster examined [ 45 , 47 , 49 , 50 , 53 , 56 , 57 , 58 ], followed by research which assessed the impact of two disastrous events which had happened in the same area (e.g. Hurricane Katrina and the Deepwater Horizon oil spill in Mississippi, and the Great East Japan earthquake and Tsunami; [ 36 , 37 , 38 , 42 , 44 , 48 ]). Other disaster types included: flooding [ 51 , 54 , 55 , 59 , 60 ], hurricanes [ 35 , 39 , 41 ], infectious disease outbreaks [ 43 , 46 ], oil spillage [ 40 ], and drought [ 52 ].

Variables of interest examined

Across the 26 retained papers: eight referred to examining the impact of SC [ 35 , 37 , 39 , 41 , 46 , 49 , 55 , 60 ]; eight examined the impact of cognitive and structural SC as separate entities [ 40 , 42 , 45 , 48 , 50 , 54 , 57 , 59 ]; one examined bridging and bonding SC as separate entities [ 58 ]; two examined the impact of CR [ 38 , 56 ]; and two employed a qualitative methodology but drew findings in relation to bonding and bridging SC, and SC generally [ 51 , 52 ]. Additionally, five papers examined the impact of the following variables: ‘community social cohesion’ [ 36 ], ‘neighbourhood connectedness’ [ 44 ], ‘social support at the community level’ [ 47 ], ‘community connectedness’ [ 43 ] and ‘sense of community’ [ 53 ]. Table 1 provides additional details on this.

How is CR and SC measured or quantified in research?

The measures used to examine CR and SC are presented Table 1 . It is apparent that there is no uniformity in how SC or CR is measured across the research. Multiple measures are used throughout the retained studies, and nearly all are unique. Additionally, SC was examined at multiple different levels (e.g. cognitive and structural, bonding and bridging), and in multiple different forms (e.g. community connectedness, community cohesion).

What is the association between CR and SC on mental wellbeing?

To best compare research, the following section reports on CR, and facets of SC separately. Please see Supplementary file 4 for additional information on retained papers methods of measuring mental wellbeing.

Community resilience

CR relates to the ability of a community to withstand, adapt and permit growth in adverse circumstances due to social structures, networks and interdependencies within the community [ 11 ].

The impact of CR on mental wellbeing was consistently positive. For example, research indicated that there was a positive association between CR and number of common mental health (i.e. anxiety and mood) treatments post-disaster [ 56 ]. Similarly, other research suggests that CR is positively related to psychological resilience, which is inversely related to depressive symptoms) [ 37 ]. The same research also concluded that CR is protective of psychological resilience and is therefore protective of depressive symptoms [ 37 ].

Social capital

SC reflects the strength of a social network, community reciprocity, and trust in people and institutions [ 14 ]. These aspects of community are usually conceptualised primarily as protective factors that enable communities to cope and adapt collectively to threats.

There were inconsistencies across research which examined the impact of abstract SC (i.e. not refined into bonding/bridging or structural/cognitive) on mental wellbeing. However, for the majority of cases, research deems SC to be beneficial. For example, research has concluded that, SC is protective against post-traumatic stress disorder [ 55 ], anxiety [ 46 ], psychological distress [ 50 ], and stress [ 46 ]. Additionally, SC has been found to facilitate post-traumatic growth [ 38 ], and also to be useful to be drawn upon in times of stress [ 52 ], both of which could be protective of mental health. Similarly, research has also found that emotional recovery following a disaster is more difficult for those who report to have low levels of SC [ 51 ].

Conversely, however, research has also concluded that when other situational factors (e.g. personal resources) were controlled for, a positive relationship between community resources and life satisfaction was no longer significant [ 60 ]. Furthermore, some research has concluded that a high level of SC can result in a community facing greater stress immediately post disaster. Indeed, one retained paper found that high levels of SC correlate with higher levels of post-traumatic stress immediately following a disaster [ 39 ]. However, in the later stages following a disaster, this relationship can reverse, with SC subsequently providing an aid to recovery [ 41 ]. By way of explanation, some researchers have suggested that communities with stronger SC carry the greatest load in terms of helping others (i.e. family, friends and neighbours) as well as themselves immediately following the disaster, but then as time passes the communities recover at a faster rate as they are able to rely on their social networks for support [ 41 ].

Cognitive and structural social capital

Cognitive SC refers to perceptions of community relations, such as trust, mutual help and attachment, and structural SC refers to what actually happens within the community, such as participation, socialising [ 16 ].

Cognitive SC has been found to be protective [ 49 ] against PTSD [ 54 , 57 ], depression [ 40 , 54 ]) mild mood disorder; [ 48 ]), anxiety [ 48 , 54 ] and increase self-efficacy [ 59 ].

For structural SC, research is again inconsistent. On the one hand, structural SC has been found to: increase perceived self-efficacy, be protective of depression [ 40 ], buffer the impact of housing damage on cognitive decline [ 42 ] and provide support during disasters and over the recovery period [ 59 ]. However, on the other hand, it has been found to have no association with PTSD [ 54 , 57 ] or depression, and is also associated with a higher prevalence of anxiety [ 54 ]. Similarly, it is also suggested by additional research that structural SC can harm women’s mental health, either due to the pressure of expectations to help and support others or feelings of isolation [ 49 ].

Bonding and bridging social capital

Bonding SC refers to connections among individuals who are emotionally close, and result in bonds to a particular group [ 17 ], and bridging SC refers to acquaintances or individuals loosely connected that span different social groups [ 18 ].

One research study concluded that both bonding and bridging SC were protective against post-traumatic stress disorder symptoms [ 58 ]. Bridging capital was deemed to be around twice as effective in buffering against post-traumatic stress disorder than bonding SC [ 58 ].

Other community variables

Community social cohesion was significantly associated with a lower risk of post-traumatic stress disorder symptom development [ 35 ], and this was apparent even whilst controlling for depressive symptoms at baseline and disaster impact variables (e.g. loss of family member or housing damage) [ 36 ]. Similarly, sense of community, community connectedness, social support at the community level and neighbourhood connectedness all provided protective benefits for a range of mental health, wellbeing and recovery variables, including: depression [ 53 ], subjective wellbeing (in older adults only) [ 43 ], psychological distress [ 47 ], happiness [ 44 ] and life satisfaction [ 53 ].

Research has also concluded that community level social support is protective against mild mood and anxiety disorder, but only for individuals who have had no previous disaster experience [ 48 ]. Additionally, a study which separated SC into social cohesion and social participation concluded that at a community level, social cohesion is protective against depression [ 49 ] whereas social participation at community level is associated with an increased risk of depression amongst women [ 49 ].

What is the impact of Infectious disease outbreaks / disasters and emergencies on community resilience?

From a cross-sectional perspective, research has indicated that disasters and emergencies can have a negative effect on certain types of SC. Specifically, cognitive SC has been found to be impacted by disaster impact, whereas structural SC has gone unaffected [ 45 ]. Disaster impact has also been shown to have a negative effect on community relationships more generally [ 52 ].

Additionally, of the eight studies which collected data at multiple time points [ 35 , 36 , 41 , 42 , 47 , 49 , 56 , 60 ], three reported the effect of a disaster on the level of SC within a community [ 40 , 42 , 49 ]. All three of these studies concluded that disasters may have a negative impact on the levels of SC within a community. The first study found that the Deepwater Horizon oil spill had a negative effect on SC and social support, and this in turn explained an overall increase in the levels of depression within the community [ 40 ]. A possible explanation for the negative effect lays in ‘corrosive communities’, known for increased social conflict and reduced social support, that are sometimes created following oil spills [ 40 ]. It is proposed that corrosive communities often emerge due to a loss of natural resources that bring social groups together (e.g., for recreational activities), as well as social disparity (e.g., due to unequal distribution of economic impact) becoming apparent in the community following disaster [ 40 ]. The second study found that SC (in the form of social cohesion, informal socialising and social participation) decreased after the 2011 earthquake and tsunami in Japan; it was suggested that this change correlated with incidence of cognitive decline [ 42 ]. However, the third study reported more mixed effects based on physical circumstances of the communities’ natural environment: Following an earthquake, those who lived in mountainous areas with an initial high level of pre-community SC saw a decrease in SC post disaster [ 49 ]. However, communities in flat areas (which were home to younger residents and had a higher population density) saw an increase in SC [ 49 ]. It was proposed that this difference could be due to the need for those who lived in mountainous areas to seek prolonged refuge due to subsequent landslides [ 49 ].

What types of intervention enhance CR and SC and protect survivors?

There were mixed effects across the 26 retained papers when examining the effect of CR and SC on mental wellbeing. However, there is evidence that an increase in SC [ 56 , 57 ], with a focus on cognitive SC [ 57 ], namely by: building social networks [ 45 , 51 , 53 ], enhancing feelings of social cohesion [ 35 , 36 ] and promoting a sense of community [ 53 ], can result in an increase in CR and potentially protect survivors’ wellbeing and mental health following a disaster. An increase in SC may also aid in decreasing the need for individual psychological interventions in the aftermath of a disaster [ 55 ]. As a result, recommendations and suggested methods to bolster CR and SC from the retained papers have been extracted and separated into general methods, preparedness and policy level implementation.

General methods

Suggested methods to build SC included organising recreational activity-based groups [ 44 ] to broaden [ 51 , 53 ] and preserve current social networks [ 42 ], introducing initiatives to increase social cohesion and trust [ 51 ], and volunteering to increase the number of social ties between residents [ 59 ]. Research also notes that it is important to take a ‘no one left behind approach’ when organising recreational and social community events, as failure to do so could induce feelings of isolation for some members of the community [ 49 ]. Furthermore, gender differences should also be considered as research indicates that males and females may react differently to community level SC (as evidence suggests males are instead more impacted by individual level SC; in comparison to women who have larger and more diverse social networks [ 49 ]). Therefore, interventions which aim to raise community level social participation, with the aim of expanding social connections and gaining support, may be beneficial [ 42 , 47 ].

Preparedness

In order to prepare for disasters, it may be beneficial to introduce community-targeted methods or interventions to increase levels of SC and CR as these may aid in ameliorating the consequences of a public health emergency or disaster [ 57 ]. To indicate which communities have low levels of SC, one study suggests implementing a 3-item scale of social cohesion to map areas and target interventions [ 42 ].

It is important to consider that communities with a high level of SC may have a lower level of risk perception, due to the established connections and supportive network they have with those around them [ 61 ]. However, for the purpose of preparedness, this is not ideal as perception of risk is a key factor when seeking to encourage behavioural adherence. This could be overcome by introducing communication strategies which emphasise the necessity of social support, but also highlights the need for additional measures to reduce residual risk [ 59 ]. Furthermore, support in the form of financial assistance to foster current community initiatives may prove beneficial to rural areas, for example through the use of an asset-based community development framework [ 52 ].

Policy level

At a policy level, the included papers suggest a range of ways that CR and SC could be bolstered and used. These include: providing financial support for community initiatives and collective coping strategies, (e.g. using asset-based community development [ 52 ]); ensuring policies for long-term recovery focus on community sustainable development (e.g. community festival and community centre activities) [ 44 ]; and development of a network amongst cooperative corporations formed for reconstruction and to organise self-help recovery sessions among residents of adjacent areas [ 58 ].

This scoping review sought to synthesise literature concerning the role of SC and CR during public health emergencies and disasters. Specifically, in this review we have examined: the methods used to measure CR and SC; the impact of CR and SC on mental wellbeing during disasters and emergencies; the impact of disasters and emergencies on CR and SC; and the types of interventions which can be used to enhance CR. To do this, data was extracted from 26 peer-reviewed journal articles. From this synthesis, several key themes have been identified, which can be used to develop guidelines and recommendations for deploying CR and SC in a public health emergency or disaster context. These key themes and resulting recommendations are summarised below.

Firstly, this review established that there is no consistent or standardised approach to measuring CR or SC within the general population. This finding is consistent with a review conducted by the World Health Organization which concludes that despite there being a number of frameworks that contain indicators across different determinants of health, there is a lack of consensus on priority areas for measurement and no widely accepted indicator [ 27 ]. As a result, there are many measures of CR and SC apparent within the literature (e.g., [ 62 , 63 ]), an example of a developed and validated measure is provided by Sherrieb, Norris and Galea [ 64 ]. Similarly, the definitions of CR and SC differ widely between researchers, which created a barrier to comparing and summarising information. Therefore, future research could seek to compare various interpretations of CR and to identify any overlapping concepts. However, a previous systemic review conducted by Patel et al. (2017) concludes that there are nine core elements of CR (local knowledge, community networks and relationships, communication, health, governance and leadership, resources, economic investment, preparedness, and mental outlook), with 19 further sub-elements therein [ 30 ]. Therefore, as CR is a multi-dimensional construct, the implications from the findings are that multiple aspects of social infrastructure may need to be considered.

Secondly, our synthesis of research concerning the role of CR and SC for ensuring mental health and wellbeing during, or following, a public health emergency or disaster revealed mixed effects. Much of the research indicates either a generally protective effect on mental health and wellbeing, or no effect; however, the literature demonstrates some potential for a high level of CR/SC to backfire and result in a negative effect for populations during, or following, a public health emergency or disaster. Considered together, our synthesis indicates that cognitive SC is the only facet of SC which was perceived as universally protective across all retained papers. This is consistent with a systematic review which also concludes that: (a) community level cognitive SC is associated with a lower risk of common mental disorders, while; (b) community level structural SC had inconsistent effects [ 65 ].

Further examination of additional data extracted from studies which found that CR/SC had a negative effect on mental health and wellbeing revealed no commonalities that might explain these effects (Please see Supplementary file 5 for additional information)

One potential explanation may come from a retained paper which found that high levels of SC result in an increase in stress level immediately post disaster [ 41 ]. This was suggested to be due to individuals having greater burdens due to wishing to help and support their wide networks as well as themselves. However, as time passes the levels of SC allow the community to come together and recover at a faster rate [ 41 ]. As this was the only retained paper which produced this finding, it would be beneficial for future research to examine boundary conditions for the positive effects of CR/SC; that is, to explore circumstances under which CR/SC may be more likely to put communities at greater risk. This further research should also include additional longitudinal research to validate the conclusions drawn by [ 41 ] as resilience is a dynamic process of adaption.

Thirdly, disasters and emergencies were generally found to have a negative effect on levels of SC. One retained paper found a mixed effect of SC in relation to an earthquake, however this paper separated participants by area in which they lived (i.e., mountainous vs. flat), which explains this inconsistent effect [ 49 ]. Dangerous areas (i.e. mountainous) saw a decrease in community SC in comparison to safer areas following the earthquake (an effect the authors attributed to the need to seek prolonged refuge), whereas participants from the safer areas (which are home to younger residents with a higher population density) saw an increase in SC [ 49 ]. This is consistent with the idea that being able to participate socially is a key element of SC [ 12 ]. Overall, however, this was the only retained paper which produced a variable finding in relation to the effect of disaster on levels of CR/SC.

Finally, research identified through our synthesis promotes the idea of bolstering SC (particularly cognitive SC) and cohesion in communities likely to be affected by disaster to improve levels of CR. This finding provides further understanding of the relationship between CR and SC; an association that has been reported in various articles seeking to provide conceptual frameworks (e.g., [ 66 , 67 ]) as well as indicator/measurement frameworks [ 27 ]. Therefore, this could be done by creating and promoting initiatives which foster SC and create bonds within the community. Papers included in the current review suggest that recreational-based activity groups and volunteering are potential methods for fostering SC and creating community bonds [ 44 , 51 , 59 ]. Similarly, further research demonstrates that feelings of social cohesion are enhanced by general social activities (e.g. fairs and parades [ 18 ]). Also, actively encouraging activities, programs and interventions which enhance connectedness and SC have been reported to be desirable to increase CR [ 68 ]. This suggestion is supported by a recent scoping review of literature [ 67 ] examined community champion approaches for the COVID-19 pandemic response and recovery and established that creating and promoting SC focused initiatives within the community during pandemic response is highly beneficial [ 67 ]. In terms of preparedness, research states that it may be beneficial for levels of SC and CR in communities at risk to be assessed, to allow targeted interventions where the population may be at most risk following an incident [ 42 , 44 ]. Additionally, from a more critical perspective, we acknowledge that ‘resilience’ can often be perceived as a focus on individual capacity to adapt to adversity rather than changing or mitigating the causes of adverse conditions [ 69 , 70 ]. Therefore, CR requires an integrated system approach across individual, community and structural levels [ 17 ]. Also, it is important that community members are engaged in defining and agreeing how community resilience is measured [ 27 ] rather than it being imposed by system leads or decision-makers.

In the aftermath of the pandemic, is it expected that there will be long-term repercussions both from an economic [ 8 ] and a mental health perspective [ 71 ]. Furthermore, the findings from this review suggest that although those in areas with high levels of SC may be negatively affected in the acute stage, as time passes, they have potential to rebound at a faster rate than those with lower levels of SC. Ongoing evaluation of the effectiveness of current initiatives as the COVID-19 pandemic progresses into a recovery phase will be invaluable for supplementing the evidence base identified through this review.

Recommendations

As a result of this review, a number of recommendations are suggested for policy and practice during public health emergencies and recovery.

Future research should seek to establish a standardised and validated approach to measuring and defining CR and SC within communities. There are ongoing efforts in this area, for example [ 72 ]. Additionally, community members should be involved in the process of defining how CR is measured.

There should be an enhanced effort to improve preparedness for public health emergencies and disasters in local communities by gauging current levels of SC and CR within communities using a standardised measure. This approach could support specific targeting of populations with low levels of CR/SC in case of a disaster or public health emergency, whilst also allowing for consideration of support for those with high levels of CR (as these populations can be heavily impacted initially following a disaster). By distinguishing levels of SC and CR, tailored community-centred approaches could be implemented, such as those listed in a guide released by PHE in 2015 [ 73 ].

CR and SC (specifically cognitive SC) should be bolstered if communities are at risk of experiencing a disaster or public health emergency. This can be achieved by using interventions which aim to increase a sense of community and create new social ties (e.g., recreational group activities, volunteering). Additionally, when aiming to achieve this, it is important to be mindful of the risk of increased levels of CR/SC to backfire, as well as seeking to advocate an integrated system approach across individual, community and structural levels.

It is necessary to be aware that although communities with high existing levels of resilience / SC may experience short-term negative consequences following a disaster, over time these communities might be able to recover at a faster rate. It is therefore important to ensure that suitable short-term support is provided to these communities in the immediate aftermath of a public health emergency or disaster.

Robust evaluation of the community resilience initiatives deployed during the COVID-19 pandemic response is essential to inform the evidence base concerning the effectiveness of CR/ SC. These evaluations should continue through the response phase and into the recovery phase to help develop our understanding of the long-term consequences of such interventions.

Limitations

Despite this review being the first in this specific topic area, there are limitations that must be considered. Firstly, it is necessary to note that communities are generally highly diverse and the term ‘community’ in academic literature is a subject of much debate (see: [ 74 ]), therefore this must be considered when comparing and collating research involving communities. Additionally, the measures of CR and SC differ substantially across research, including across the 26 retained papers used in the current review. This makes the act of comparing and collating research findings very difficult. This issue is highlighted as a key outcome from this review, and suggestions for how to overcome this in future research are provided. Additionally, we acknowledge that there will be a relationship between CR & SC even where studies measure only at individual or community level. A review [ 75 ] on articulating a hypothesis of the link to health inequalities suggests that wider structural determinants of health need to be accounted for. Secondly, despite the final search strategy encompassing terms for both CR and SC, only one retained paper directly measured CR; thus, making the research findings more relevant to SC. Future research could seek to focus on CR to allow for a comparison of findings. Thirdly, the review was conducted early in the COVID-19 pandemic and so does not include more recent publications focusing on resilience specifically in the context of COVID-19. Regardless of this fact, the synthesis of, and recommendations drawn from, the reviewed studies are agnostic to time and specific incident and contain critical elements necessary to address as the pandemic moves from response to recovery. Further research should review the effectiveness of specific interventions during the COVID-19 pandemic for collation in a subsequent update to this current paper. Fourthly, the current review synthesises findings from countries with individualistic and collectivistic cultures, which may account for some variation in the findings. Lastly, despite choosing a scoping review method for ease of synthesising a wide literature base for use by public health emergency researchers in a relatively tight timeframe, there are disadvantages of a scoping review approach to consider: (1) quality appraisal of retained studies was not carried out; (2) due to the broad nature of a scoping review, more refined and targeted reviews of literature (e.g., systematic reviews) may be able to provide more detailed research outcomes. Therefore, future research should seek to use alternative methods (e.g., empirical research, systematic reviews of literature) to add to the evidence base on CR and SC impact and use in public health practice.

This review sought to establish: (1) How CR and SC are quantified in research?; (2) The impact of community resilience on mental wellbeing?; (3) The impact of infectious disease outbreaks, disasters and emergencies on community resilience and social capital?; and, (4) What types of interventions enhance community resilience and social capital?. The chosen search strategy yielded 26 relevant papers from which we were able extract information relating to the aims of this review.

Results from the review revealed that CR and SC are not measured consistently across research. The impact of CR / SC on mental health and wellbeing during emergencies and disasters is mixed (with some potential for backlash), however the literature does identify cognitive SC as particularly protective. Although only a small number of papers compared CR or SC before and after a disaster, the findings were relatively consistent: SC or CR is negatively impacted by a disaster. Methods suggested to bolster SC in communities were centred around social activities, such as recreational group activities and volunteering. Recommendations for both research and practice (with a particular focus on the ongoing COVID-19 pandemic) are also presented.

Availability of data and materials

The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.

Abbreviations

Social Capital

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This study was supported by the National Institute for Health Research Research Unit (NIHR HPRU) in Emergency Preparedness and Response, a partnership between Public Health England, King’s College London and the University of East Anglia. The views expressed are those of the author(s) and not necessarily those of the NIHR, Public Health England, the UK Health Security Agency or the Department of Health and Social Care [Grant number: NIHR20008900]. Part of this work has been funded by the Office for Health Improvement and Disparities, Department of Health and Social Care, as part of a Collaborative Agreement with Leeds Beckett University.

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DW, JSo and JSt had the main idea for the review. The search strategy and eligibility criteria were devised by CH, DW, JSo and JSt. CH conducted the database searches. CH and DW conducted duplicate, title and abstract and full text screening in accordance with inclusion criteria. CH conducted data extraction, CH and DW carried out the analysis and drafted the initial manuscript. All authors provided critical revision of intellectual content. All authors approved the final manuscript.

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Hall, C.E., Wehling, H., Stansfield, J. et al. Examining the role of community resilience and social capital on mental health in public health emergency and disaster response: a scoping review. BMC Public Health 23 , 2482 (2023). https://doi.org/10.1186/s12889-023-17242-x

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DOI : https://doi.org/10.1186/s12889-023-17242-x

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The JKU’s New Image Campaign Focuses on the Importance of “University Medicine”

University Medicine not only stands for conducting research to support cutting-edge medicine, but also providing high-quality patience care in Upper Austria.

The Johannes Kepler University Linz has launched a new image campaign to spotlight its medical innovations along with those involved whose lives have been touched by successes in university medicine.

JKU Rector Meinhard Lukas : "There is hardly a topic that is as crucial to all of us as health. The past few years have brought about a new awareness of just how we, as a society, deal with illnesses, ‘becoming healthy’, and ‘staying healthy’. While medical research has always been at the center of this debate, its significance has recently been pushed somewhat to the background. Wrongly so. Our new campaign shines a spotlight on research at the JKU Faculty of Medicine, along with the incredible progress and advancements in recent years and the way people's lives have substantially improved."

Be it in the areas of engineering, art, culture, or medicine, Upper Austria and its state capital of Linz have always been a prime location in support of long-term innovation. Trendsetting landmarks, such as the Ars Electronica Center, the Linz Cloud of Sound, the Opera House, the Lentos and Nordico museums, and the voestalpine Stahlwelt just to name a few, have become just as much an integral part of Linz's identity as the Pöstlingberg church and its grotto railway, the Linz Torte, and the Mariendom cathedral. That which was once considered new and unknown yesterday is emerging as a proud legacy today. As a comparatively young institution, the JKU’s Faculty of Medicine aims to continuing growing and driving innovation forward by supporting cutting-edge medical research that includes new treatments and interventions, along with breakthroughs such as aortic arch replacement, aneurysm clippings, and teaching anatomy virtually at the JKU medSPACE. This – and more - is available in Linz and Upper Austria – a city and a region that is becoming synonymous with progress and advancement.

Elgin Drda , Vice-Rector for Medicine, and Dean of the JKU's Faculty of Medicine remarked: “Since the inception of the JKU’s Faculty of Medicine, our center of focus has been our patients’ welfare and well-being. Our professors are not only committed to caring for patients in accordance with recent scientific methods, they are also committed to conducting cutting-edge research and educating the next generation of physicians. We aim to provide a medical education program in Upper Austria that is dedicated to people and their health. Our new image campaign illustrates just what university medicine can do for patients and for the region as a whole.”

The JKU Faculty of Medicine opened its doors in 2014, and in 2021, the JKU MED Campus was unveiled in the heart of Linz. Since then, it has been a central hub for medical education and research.

The new campaign aims to showcase just how important University Medicine is in the region and, above all, for its residents, as well as to inspire prospective students, young physicians, and everyone in Upper Austria and Linz to take an interest in university medicine!

Editorial articles, images, and information about the image campaign are available here

Facts & Figures about the New "University Medicine" Image Campaign

Campaign period: Now to June 2023
Target area: Upper Austria
Formats: 16 sheet posters, city lights, online and social media advertising as well as print images
Implemented together with creative advertising EN GARDE , opens an external URL in a new window in Graz; online animation by Pulpmedia , opens an external URL in a new window
A series of articles in leading Upper Austrian media about University Medicine for the people

Selected campaign images

Mariendom Cathedral, Linz Cloud of Sound & a hybrid OP
Nordico, Grotto Railway & Aneurysm clipping
Ars Electronica, Linz Torte & the JKU medSPACE

Downloads & Links

Linz Torte Image , opens in new window
Press release (full text, German only) , opens in new window
Mariendom Cathedral Image , opens in new window
Nordico Image , opens in new window

Johannes Kepler University Linz

Altenberger Straße 69

4040 Linz, Austria

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