why is critical thinking important to psychological science

OPINION article

Redefining critical thinking: teaching students to think like scientists.

$\r\nRodney M. Schmaltz*$

Department of Psychology, MacEwan University, Edmonton, AB, Canada

From primary to post-secondary school, critical thinking (CT) is an oft cited focus or key competency (e.g., DeAngelo et al., 2009 ; California Department of Education, 2014 ; Alberta Education, 2015 ; Australian Curriculum Assessment and Reporting Authority, n.d. ). Unfortunately, the definition of CT has become so broad that it can encompass nearly anything and everything (e.g., Hatcher, 2000 ; Johnson and Hamby, 2015 ). From discussion of Foucault, critique and the self ( Foucault, 1984 ) to Lawson's (1999) definition of CT as the ability to evaluate claims using psychological science, the term critical thinking has come to refer to an ever-widening range of skills and abilities. We propose that educators need to clearly define CT, and that in addition to teaching CT, a strong focus should be placed on teaching students how to think like scientists. Scientific thinking is the ability to generate, test, and evaluate claims, data, and theories (e.g., Bullock et al., 2009 ; Koerber et al., 2015 ). Simply stated, the basic tenets of scientific thinking provide students with the tools to distinguish good information from bad. Students have access to nearly limitless information, and the skills to understand what is misinformation or a questionable scientific claim is crucially important ( Smith, 2011 ), and these skills may not necessarily be included in the general teaching of critical thinking ( Wright, 2001 ).

This is an issue of more than semantics. While some definitions of CT include key elements of the scientific method (e.g., Lawson, 1999 ; Lawson et al., 2015 ), this emphasis is not consistent across all interpretations of CT ( Huber and Kuncel, 2016 ). In an attempt to provide a comprehensive, detailed definition of CT, the American Philosophical Association (APA), outlined six CT skills, 16 subskills, and 19 dispositions ( Facione, 1990 ). Skills include interpretation, analysis, and inference; dispositions include inquisitiveness and open-mindedness. 1 From our perspective, definitions of CT such as those provided by the APA or operationally defined by researchers in the context of a scholarly article (e.g., Forawi, 2016 ) are not problematic—the authors clearly define what they are referring to as CT. Potential problems arise when educators are using different definitions of CT, or when the banner of CT is applied to nearly any topic or pedagogical activity. Definitions such as those provided by the APA provide a comprehensive framework for understanding the multi-faceted nature of CT, however the definition is complex and may be difficult to work with at a policy level for educators, especially those who work primarily with younger students.

The need to develop scientific thinking skills is evident in studies showing that 55% of undergraduate students believe that a full moon causes people to behave oddly, and an estimated 67% of students believe creatures such as Bigfoot and Chupacabra exist, despite the lack of scientific evidence supporting these claims ( Lobato et al., 2014 ). Additionally, despite overwhelming evidence supporting the existence of anthropogenic climate change, and the dire need to mitigate its effects, many people still remain skeptical of climate change and its impact ( Feygina et al., 2010 ; Lewandowsky et al., 2013 ). One of the goals of education is to help students foster the skills necessary to be informed consumers of information ( DeAngelo et al., 2009 ), and providing students with the tools to think scientifically is a crucial component of reaching this goal. By focusing on scientific thinking in conjunction with CT, educators may be better able design specific policies that aim to facilitate the necessary skills students should have when they enter post-secondary training or the workforce. In other words, students should leave secondary school with the ability to rule out rival hypotheses, understand that correlation does not equal causation, the importance of falsifiability and replicability, the ability to recognize extraordinary claims, and use the principle of parsimony (e.g., Lett, 1990 ; Bartz, 2002 ).

Teaching scientific thinking is challenging, as people are vulnerable to trusting their intuitions and subjective observations and tend to prioritize them over objective scientific findings (e.g., Lilienfeld et al., 2012 ). Students and the public at large are prone to naïve realism, or the tendency to believe that our experiences and observations constitute objective reality ( Ross and Ward, 1996 ), when in fact our experiences and observations are subjective and prone to error (e.g., Kahneman, 2011 ). Educators at the post-secondary level tend to prioritize scientific thinking ( Lilienfeld, 2010 ), however many students do not continue on to a post-secondary program after they have completed high school. Further, students who are told they are learning critical thinking may believe they possess the skills to accurately assess the world around them. However, if they are not taught the specific skills needed to be scientifically literate, they may still fall prey to logical fallacies and biases. People tend to underestimate or not understand fallacies that can prevent them from making sound decisions ( Lilienfeld et al., 2001 ; Pronin et al., 2004 ; Lilienfeld, 2010 ). Thus, it is reasonable to think that a person who has not been adequately trained in scientific thinking would nonetheless consider themselves a strong critical thinker, and therefore would be even less likely consider his or her own personal biases. Another concern is that when teaching scientific thinking there is always the risk that students become overly critical or cynical (e.g., Mercier et al., 2017 ). By this, a student may be skeptical of nearly all findings, regardless of the supporting evidence. By incorporating and focusing on cognitive biases, instructors can help students understand their own biases, and demonstrate how the rigor of the scientific method can, at least partially, control for these biases.

Teaching CT remains controversial and confusing for many instructors ( Bensley and Murtagh, 2012 ). This is partly due to the lack of clarity in the definition of CT and the wide range of methods proposed to best teach CT ( Abrami et al., 2008 ; Bensley and Murtagh, 2012 ). For instance, Bensley and Spero (2014) found evidence for the effectiveness of direct approaches to teaching CT, a claim echoed in earlier research ( Abrami et al., 2008 ; Marin and Halpern, 2011 ). Despite their positive findings, some studies have failed to find support for measures of CT ( Burke et al., 2014 ) and others have found variable, yet positive, support for instructional methods ( Dochy et al., 2003 ). Unfortunately, there is a lack of research demonstrating the best pedagogical approaches to teaching scientific thinking at different grade levels. More research is needed to provide an empirically grounded approach to teach scientific thinking, and there is also a need to develop evidence based measures of scientific thinking that are grade and age appropriate. One approach to teaching scientific thinking may be to frame the topic in its simplest terms—the ability to “detect baloney” ( Sagan, 1995 ).

Sagan (1995) has promoted the tools necessary to recognize poor arguments, fallacies to avoid, and how to approach claims using the scientific method. The basic tenets of Sagan's argument apply to most claims, and have the potential to be an effective teaching tool across a range of abilities and ages. Sagan discusses the idea of a baloney detection kit, which contains the “tools” for skeptical thinking. The development of “baloney detection kits” which include age-appropriate scientific thinking skills may be an effective approach to teaching scientific thinking. These kits could include the style of exercises that are typically found under the banner of CT training (e.g., group discussions, evaluations of arguments) with a focus on teaching scientific thinking. An empirically validated kit does not yet exist, though there is much to draw from in the literature on pedagogical approaches to correcting cognitive biases, combatting pseudoscience, and teaching methodology (e.g., Smith, 2011 ). Further research is needed in this area to ensure that the correct, and age-appropriate, tools are part of any baloney detection kit.

Teaching Sagan's idea of baloney detection in conjunction with CT provides educators with a clear focus—to employ a pedagogical approach that helps students create sound and cogent arguments while avoiding falling prey to “baloney”. This is not to say that all of the information taught under the current banner of “critical thinking” is without value. In fact, many of the topics taught under the current approach of CT are important, even though they would not fit within the framework of some definitions of critical thinking. If educators want to ensure that students have the ability to be accurate consumers of information, a focus should be placed on including scientific thinking as a component of the science curriculum, as well as part of the broader teaching of CT.

Educators need to be provided with evidence-based approaches to teach the principles of scientific thinking. These principles should be taught in conjunction with evidence-based methods that mitigate the potential for fallacious reasoning and false beliefs. At a minimum, when students first learn about science, there should also be an introduction to the basics tenets of scientific thinking. Courses dedicated to promoting scientific thinking may also be effective. A course focused on cognitive biases, logical fallacies, and the hallmarks of scientific thinking adapted for each grade level may provide students with the foundation of solid scientific thinking skills to produce and evaluate arguments, and allow expansion of scientific thinking into other scholastic areas and classes. Evaluations of the efficacy of these courses would be essential, along with research to determine the best approach to incorporate scientific thinking into the curriculum.

If instructors know that students have at least some familiarity with the fundamental tenets of scientific thinking, the ability to expand and build upon these ideas in a variety of subject specific areas would further foster and promote these skills. For example, when discussing climate change, an instructor could add a brief discussion of why some people reject the science of climate change by relating this back to the information students will be familiar with from their scientific thinking courses. In terms of an issue like climate change, many students may have heard in political debates or popular culture that global warming trends are not real, or a “hoax” ( Lewandowsky et al., 2013 ). In this case, only teaching the data and facts may not be sufficient to change a student's mind about the reality of climate change ( Lewandowsky et al., 2012 ). Instructors would have more success by presenting students with the data on global warming trends as well as information on the biases that could lead some people reject the data ( Kowalski and Taylor, 2009 ; Lewandowsky et al., 2012 ). This type of instruction helps educators create informed citizens who are better able to guide future decision making and ensure that students enter the job market with the skills needed to be valuable members of the workforce and society as a whole.

By promoting scientific thinking, educators can ensure that students are at least exposed to the basic tenets of what makes a good argument, how to create their own arguments, recognize their own biases and those of others, and how to think like a scientist. There is still work to be done, as there is a need to put in place educational programs built on empirical evidence, as well as research investigating specific techniques to promote scientific thinking for children in earlier grade levels and develop measures to test if students have acquired the necessary scientific thinking skills. By using an evidence based approach to implement strategies to promote scientific thinking, and encouraging researchers to further explore the ideal methods for doing so, educators can better serve their students. When students are provided with the core ideas of how to detect baloney, and provided with examples of how baloney detection relates to the real world (e.g., Schmaltz and Lilienfeld, 2014 ), we are confident that they will be better able to navigate through the oceans of information available and choose the right path when deciding if information is valid.

Author Contribution

RS was the lead author and this paper, and both EJ and NW contributed equally.

Conflict of Interest Statement

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

1. ^ There is some debate about the role of dispositional factors in the ability for a person to engage in critical thinking, specifically that dispositional factors may mitigate any attempt to learn CT. The general consensus is that while dispositional traits may play a role in the ability to think critically, the general skills to be a critical thinker can be taught ( Niu et al., 2013 ; Abrami et al., 2015 ).

Abrami, P. C., Bernard, R. M., Borokhovski, E., Waddington, D. I., Wade, C. A., and Persson, T. (2015). Strategies for teaching students to think critically a meta-analysis. Rev. Educ. Res. 85, 275–314. doi: 10.3102/0034654308326084

CrossRef Full Text | Google Scholar

Abrami, P. C., Bernard, R. M., Borokhovski, E., Wade, A., Surkes, M. A., Tamim, R., et al. (2008). Instructional interventions affecting critical thinking skills and dispositions: a stage 1 meta-analysis. Rev. Educ. Res. 78, 1102–1134. doi: 10.3102/0034654308326084

Alberta Education (2015). Ministerial Order on Student Learning . Available online at: https://education.alberta.ca/policies-and-standards/student-learning/everyone/ministerial-order-on-student-learning-pdf/

Australian Curriculum Assessment and Reporting Authority (n.d.). Available online at: http://www.australiancurriculum.edu.au

Bartz, W. R. (2002). Teaching skepticism via the CRITIC acronym and the skeptical inquirer. Skeptical Inquirer 17, 42–44.

Google Scholar

Bensley, D. A., and Murtagh, M. P. (2012). Guidelines for a scientific approach to critical thinking assessment. Teach. Psychol. 39, 5–16. doi: 10.1177/0098628311430642

Bensley, D. A., and Spero, R. A. (2014). Improving critical thinking skills and metacognitive monitoring through direct infusion. Think. Skills Creativ. 12, 55–68. doi: 10.1016/j.tsc.2014.02.001

Bullock, M., Sodian, B., and Koerber, S. (2009). “Doing experiments and understanding science: development of scientific reasoning from childhood to adulthood,” in Human Development from Early Childhood to Early Adulthood: Findings from a 20 Year Longitudinal Study , eds W. Schneider and M. Bullock (New York, NY: Psychology Press), 173–197.

Burke, B. L., Sears, S. R., Kraus, S., and Roberts-Cady, S. (2014). Critical analysis: a comparison of critical thinking changes in psychology and philosophy classes. Teach. Psychol. 41, 28–36. doi: 10.1177/0098628313514175

California Department of Education (2014). Standard for Career Ready Practice . Available online at: http://www.cde.ca.gov/nr/ne/yr14/yr14rel22.asp

DeAngelo, L., Hurtado, S., Pryor, J. H., Kelly, K. R., Santos, J. L., and Korn, W. S. (2009). The American College Teacher: National Norms for the 2007-2008 HERI Faculty Survey . Los Angeles, CA: Higher Education Research Institute.

Dochy, F., Segers, M., Van den Bossche, P., and Gijbels, D. (2003). Effects of problem-based learning: a meta-analysis. Learn. Instruct. 13, 533–568. doi: 10.1016/S0959-4752(02)00025-7

Facione, P. A. (1990). Critical thinking: A Statement of Expert Consensus for Purposes of Educational Assessment and Instruction. Research Findings and Recommendations. Newark, DE: American Philosophical Association.

Feygina, I., Jost, J. T., and Goldsmith, R. E. (2010). System justification, the denial of global warming, and the possibility of ‘system-sanctioned change’. Pers. Soc. Psychol. Bull. 36, 326–338. doi: 10.1177/0146167209351435

PubMed Abstract | CrossRef Full Text | Google Scholar

Forawi, S. A. (2016). Standard-based science education and critical thinking. Think. Skills Creativ. 20, 52–62. doi: 10.1016/j.tsc.2016.02.005

Foucault, M. (1984). The Foucault Reader . New York, NY: Pantheon.

Hatcher, D. L. (2000). Arguments for another definition of critical thinking. Inquiry 20, 3–8. doi: 10.5840/inquiryctnews20002016

Huber, C. R., and Kuncel, N. R. (2016). Does college teach critical thinking? A meta-analysis. Rev. Educ. Res. 86, 431–468. doi: 10.3102/0034654315605917

Johnson, R. H., and Hamby, B. (2015). A meta-level approach to the problem of defining “Critical Thinking”. Argumentation 29, 417–430. doi: 10.1007/s10503-015-9356-4

Kahneman, D. (2011). Thinking, Fast and Slow . New York, NY: Farrar, Straus and Giroux.

Koerber, S., Mayer, D., Osterhaus, C., Schwippert, K., and Sodian, B. (2015). The development of scientific thinking in elementary school: a comprehensive inventory. Child Dev. 86, 327–336. doi: 10.1111/cdev.12298

Kowalski, P., and Taylor, A. K. (2009). The effect of refuting misconceptions in the introductory psychology class. Teach. Psychol. 36, 153–159. doi: 10.1080/00986280902959986

Lawson, T. J. (1999). Assessing psychological critical thinking as a learning outcome for psychology majors. Teach. Psychol. 26, 207–209. doi: 10.1207/S15328023TOP260311

CrossRef Full Text

Lawson, T. J., Jordan-Fleming, M. K., and Bodle, J. H. (2015). Measuring psychological critical thinking: an update. Teach. Psychol. 42, 248–253. doi: 10.1177/0098628315587624

Lett, J. (1990). A field guide to critical thinking. Skeptical Inquirer , 14, 153–160.

Lewandowsky, S., Ecker, U. H., Seifert, C. M., Schwarz, N., and Cook, J. (2012). Misinformation and its correction: continued influence and successful debiasing. Psychol. Sci. Public Interest 13, 106–131. doi: 10.1177/1529100612451018

Lewandowsky, S., Oberauer, K., and Gignac, G. E. (2013). NASA faked the moon landing—therefore, (climate) science is a hoax: an anatomy of the motivated rejection of science. Psychol. Sci. 24, 622–633. doi: 10.1177/0956797612457686

Lilienfeld, S. O. (2010). Can psychology become a science? Pers. Individ. Dif. 49, 281–288. doi: 10.1016/j.paid.2010.01.024

Lilienfeld, S. O., Ammirati, R., and David, M. (2012). Distinguishing science from pseudoscience in school psychology: science and scientific thinking as safeguards against human error. J. Sch. Psychol. 50, 7–36. doi: 10.1016/j.jsp.2011.09.006

Lilienfeld, S. O., Lohr, J. M., and Morier, D. (2001). The teaching of courses in the science and pseudoscience of psychology: useful resources. Teach. Psychol. 28, 182–191. doi: 10.1207/S15328023TOP2803_03

Lobato, E., Mendoza, J., Sims, V., and Chin, M. (2014). Examining the relationship between conspiracy theories, paranormal beliefs, and pseudoscience acceptance among a university population. Appl. Cogn. Psychol. 28, 617–625. doi: 10.1002/acp.3042

Marin, L. M., and Halpern, D. F. (2011). Pedagogy for developing critical thinking in adolescents: explicit instruction produces greatest gains. Think. Skills Creativ. 6, 1–13. doi: 10.1016/j.tsc.2010.08.002

Mercier, H., Boudry, M., Paglieri, F., and Trouche, E. (2017). Natural-born arguers: teaching how to make the best of our reasoning abilities. Educ. Psychol. 52, 1–16. doi: 10.1080/00461520.2016.1207537

Niu, L., Behar-Horenstein, L. S., and Garvan, C. W. (2013). Do instructional interventions influence college students' critical thinking skills? A meta-analysis. Educ. Res. Rev. 9, 114–128. doi: 10.1016/j.edurev.2012.12.002

Pronin, E., Gilovich, T., and Ross, L. (2004). Objectivity in the eye of the beholder: divergent perceptions of bias in self versus others. Psychol. Rev. 111, 781–799. doi: 10.1037/0033-295X.111.3.781

Ross, L., and Ward, A. (1996). “Naive realism in everyday life: implications for social conflict and misunderstanding,” in Values and Knowledge , eds E. S. Reed, E. Turiel, T. Brown, E. S. Reed, E. Turiel and T. Brown (Hillsdale, NJ: Lawrence Erlbaum Associates Inc.), 103–135.

Sagan, C. (1995). Demon-Haunted World: Science as a Candle in the Dark . New York, NY: Random House.

Schmaltz, R., and Lilienfeld, S. O. (2014). Hauntings, homeopathy, and the Hopkinsville Goblins: using pseudoscience to teach scientific thinking. Front. Psychol. 5:336. doi: 10.3389/fpsyg.2014.00336

Smith, J. C. (2011). Pseudoscience and Extraordinary Claims of the Paranormal: A Critical Thinker's Toolkit . New York, NY: John Wiley and Sons.

Wright, I. (2001). Critical thinking in the schools: why doesn't much happen? Inform. Logic 22, 137–154. doi: 10.22329/il.v22i2.2579

Keywords: scientific thinking, critical thinking, teaching resources, skepticism, education policy

Citation: Schmaltz RM, Jansen E and Wenckowski N (2017) Redefining Critical Thinking: Teaching Students to Think like Scientists. Front. Psychol . 8:459. doi: 10.3389/fpsyg.2017.00459

Received: 13 December 2016; Accepted: 13 March 2017; Published: 29 March 2017.

Reviewed by:

Copyright © 2017 Schmaltz, Jansen and Wenckowski. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY) . The use, distribution or reproduction in other forums is permitted, provided the original author(s) or licensor are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Rodney M. Schmaltz, [email protected]

Disclaimer: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.

Subject List
Take a Tour
For Authors
Subscriber Services
Publications
African American Studies
African Studies
American Literature
Anthropology
Architecture Planning and Preservation
Art History
Atlantic History
Biblical Studies
British and Irish Literature
Childhood Studies
Chinese Studies
Cinema and Media Studies
Communication
Criminology
Environmental Science
Evolutionary Biology
International Law
International Relations
Islamic Studies
Jewish Studies
Latin American Studies
Latino Studies
Linguistics
Literary and Critical Theory
Medieval Studies
Military History
Political Science
Public Health
Renaissance and Reformation
Social Work
Urban Studies
Victorian Literature
Browse All Subjects

How to Subscribe

Free Trials

In This Article Expand or collapse the "in this article" section Critical Thinking

Introduction, general overviews.

Importance of Thinking Critically
Defining Critical Thinking
General Skills
Specific Skills
Metacognitive Monitoring Skills
Critical Thinking Dispositions
Teaching Specific Skills
Encouraging a Disposition toward Thinking Critically
Transfer to Other Domains
Metacognitive Monitoring
General or Comprehensive Assessments
Metacognition Assessments
Critical Thinking Disposition Assessments
Thinking Critically about Critical Thinking

Other Subject Areas

Forthcoming articles expand or collapse the "forthcoming articles" section.

Data Visualization
Executive Functions in Childhood
Remote Work
Find more forthcoming articles...
Export Citations
Share This Facebook LinkedIn Twitter

Critical Thinking by Heather Butler , Diane Halpern LAST REVIEWED: 29 November 2011 LAST MODIFIED: 29 November 2011 DOI: 10.1093/obo/9780199828340-0019

Critical thinking has been described in many ways, but researchers generally agree that critical thinking involves rational, purposeful, and goal-directed thinking (see Defining Critical Thinking ). Diane F. Halpern defined critical thinking as an attempt to increase the probability of a desired outcome (e.g., making a sound decision, successfully solving a problem) by using certain cognitive skills and strategies. Critical thinking is more than just a collection of skills and strategies: it is a disposition toward engaging with problems. Critical thinkers are flexible, open-minded, persistent, and willing to exert mental energy working on tough problems. Unlike poor thinkers, critical thinkers are willing to admit they have made an error in judgment if confronted with contradictory evidence, and they operate on autopilot much less than poor thinkers (see Critical Thinking Dispositions ). There is good evidence that critical thinking skills and dispositions can be taught (see Teaching Critical Thinking ). This guide includes (a) sources that extol the importance of critical thinking, (b) research that identifies specific critical thinking skills and conceptualizations of critical thinking dispositions, (c) a list of the best practices for teaching critical thinking skills and dispositions, and (d) a review of research into ways of assessing critical thinking skills and dispositions (see Assessments ).

The sources highlighted here include textbooks, literature reviews, and meta-analyses related to critical thinking. These contributions come from both psychological ( Halpern 2003 ; Nisbett 1993 ; Sternberg, et al. 2007 ) and philosophical ( Ennis 1962 , Facione 1990 ) perspectives. Many of these general overviews are textbooks ( Facione 2011b ; Halpern 2003 ; Nisbett 1993 ; Sternberg, et al. 2007 ), while the other sources are review articles or commentaries. Most resources were intended for a general audience, but Sternberg, et al. 2007 was written specifically to address critical thinking in psychology. Those interested in a historical reference are referred to Ennis 1962 , which is credited by some as renewing contemporary interest in critical thinking. Those interested in a more recent conceptualization of critical thinking are referred to Facione 2011a , which is a short introduction to the field of critical thinking that would be appropriate for those new to the field, or Facione 1990 , which summarizes a collaborative definition of critical thinking among philosophers using the Delphi method. Facione 2011b would be a valuable resource for philosophers teaching critical thinking or logic courses to general audiences. For psychologists teaching critical thinking courses to a general audience, Halpern 2003 , an empirically based textbook, covers a wide range of topics; a new edition is expected soon. Fisher 2001 is also intended for general audiences and teaches a wide variety of critical thinking skills. Nisbett 1993 tackles the question of whether critical thinking skills can be taught and provides ample empirical evidence to that end. Sternberg, et al. 2007 is a good resource for psychology students interested in learning how to improve their scientific reasoning skills, a specific set of thinking skills needed by psychology and other science students.

Ennis, Robert H. 1962. A concept of critical thinking: A proposed basis of research in the teaching and evaluation of critical thinking. Harvard Educational Review 32:81–111.

A discussion of how critical thinking is conceptualized from a philosopher’s perspective. Critical of psychology’s definition of critical thinking at the time. Emphasizes twelve aspects of critical thinking.

Facione, Peter A. 1990. Critical thinking: A statement of expert consensus for purposes of educational assessment and instruction; Executive Summary of The Delphi Report . Millbrae, CA: California Academic Press.

Describes the critical thinking movement, definitions of critical thinking agreed upon by philosophers using the Delphi method, the assessment of critical thinking, and how critical thinking can be taught.

Facione, Peter A. 2011a. Critical thinking: What it is and why it counts . Millbrae, CA: Insight Assessment.

This accessible paper defines critical thinking, elaborates on specific critical thinking skills, and discusses what it means to have (or not have) a critical thinking disposition. A distinction is made between system 1 (shallow processing) and system 2 (deeper processing) thinking. Good resource for students new to the field.

Facione, Peter A. 2011b. THINK critically . Upper Saddle River, NJ: Prentice Hall.

Written from a philosophical perspective this critical thinking textbook emphasizes the application of critical thinking to the real world and offers positive examples of critical thinking. Chapters cover inductive, deductive, comparative, ideological, and empirical reasoning

Fisher, Alec. 2001. Critical thinking: An introduction . Cambridge, UK: Cambridge Univ. Press.

Textbook intended for college students discusses various types of reasoning, causality, argument analysis, and decision making. Includes exercises for students and teachers.

Halpern, Diane F. 2003. Thought & knowledge: An introduction to critical thinking . 4th ed. Mahwah, NJ: Lawrence Erlbaum.

This textbook, written by a cognitive psychologist, is grounded in theory and research from the learning sciences and offers practical examples. Chapters include an introduction to the topic and the correlates of critical thinking, memory, thought and language, reasoning, analyzing arguments, thinking as hypothesis testing, likelihood and uncertainty, decision making, development of problem-solving skills, and creative thinking.

Nisbett, Richard E. 1993. Rules for reasoning . Hillsdale, NJ: Lawrence Erlbaum.

This text is rich with empirical evidence that critical thinking skills can be taught to undergraduate and graduate students. Each chapter discusses research on an aspect of reasoning (e.g., statistical reasoning, heuristics, inductive reasoning) with special emphasis on teaching the application of these skills to everyday problems.

Sternberg, Robert J., Henry L. Roediger III, and Diane F. Halpern, eds. 2007. Critical thinking in psychology . New York: Cambridge Univ. Press.

This edited book explores several aspects of critical thinking that are needed to fully understand key topics in psychology such as experiment research, statistical inference, case studies, logical fallacies, and ethical judgments. Experts discuss the critical thinking strategies they engage in. Interesting discussion of historical breakthroughs due to critical thinking.

Users without a subscription are not able to see the full content on this page. Please subscribe or login .

Oxford Bibliographies Online is available by subscription and perpetual access to institutions. For more information or to contact an Oxford Sales Representative click here .

About Psychology »
Meet the Editorial Board »
Abnormal Psychology
Academic Assessment
Acculturation and Health
Action Regulation Theory
Action Research
Addictive Behavior
Adolescence
Adoption, Social, Psychological, and Evolutionary Perspect...
Advanced Theory of Mind
Affective Forecasting
Affirmative Action
Ageism at Work
Allport, Gordon
Alzheimer’s Disease
Ambulatory Assessment in Behavioral Science
Analysis of Covariance (ANCOVA)
Animal Behavior
Animal Learning
Anxiety Disorders
Art and Aesthetics, Psychology of
Assessment and Clinical Applications of Individual Differe...
Attachment in Social and Emotional Development across the ...
Attention-Deficit/Hyperactivity Disorder (ADHD) in Adults
Attention-Deficit/Hyperactivity Disorder (ADHD) in Childre...
Attitudinal Ambivalence
Attraction in Close Relationships
Attribution Theory
Authoritarian Personality
Bayesian Statistical Methods in Psychology
Behavior Therapy, Rational Emotive
Behavioral Economics
Behavioral Genetics
Belief Perseverance
Bereavement and Grief
Biological Psychology
Birth Order
Body Image in Men and Women
Bystander Effect
Categorical Data Analysis in Psychology
Childhood and Adolescence, Peer Victimization and Bullying...
Clark, Mamie Phipps
Clinical Neuropsychology
Clinical Psychology
Cognitive Consistency Theories
Cognitive Dissonance Theory
Cognitive Neuroscience
Communication, Nonverbal Cues and
Comparative Psychology
Competence to Stand Trial: Restoration Services
Competency to Stand Trial
Computational Psychology
Conflict Management in the Workplace
Conformity, Compliance, and Obedience
Consciousness
Coping Processes
Correspondence Analysis in Psychology
Counseling Psychology
Creativity at Work
Critical Thinking
Cross-Cultural Psychology
Cultural Psychology
Daily Life, Research Methods for Studying
Data Science Methods for Psychology
Data Sharing in Psychology
Death and Dying
Deceiving and Detecting Deceit
Defensive Processes
Depressive Disorders
Development, Prenatal
Developmental Psychology (Cognitive)
Developmental Psychology (Social)
Diagnostic and Statistical Manual of Mental Disorders (DSM...
Discrimination
Dissociative Disorders
Drugs and Behavior
Eating Disorders
Ecological Psychology
Educational Settings, Assessment of Thinking in
Effect Size
Embodiment and Embodied Cognition
Emerging Adulthood
Emotional Intelligence
Empathy and Altruism
Employee Stress and Well-Being
Environmental Neuroscience and Environmental Psychology
Ethics in Psychological Practice
Event Perception
Evolutionary Psychology
Expansive Posture
Experimental Existential Psychology
Exploratory Data Analysis
Eyewitness Testimony
Eysenck, Hans
Factor Analysis
Festinger, Leon
Five-Factor Model of Personality
Flynn Effect, The
Forensic Psychology
Forgiveness
Friendships, Children's
Fundamental Attribution Error/Correspondence Bias
Gambler's Fallacy
Game Theory and Psychology
Geropsychology, Clinical
Global Mental Health
Habit Formation and Behavior Change
Health Psychology
Health Psychology Research and Practice, Measurement in
Heider, Fritz
Heuristics and Biases
History of Psychology
Human Factors
Humanistic Psychology
Implicit Association Test (IAT)
Industrial and Organizational Psychology
Inferential Statistics in Psychology
Insanity Defense, The
Intelligence
Intelligence, Crystallized and Fluid
Intercultural Psychology
Intergroup Conflict
International Classification of Diseases and Related Healt...
International Psychology
Interviewing in Forensic Settings
Intimate Partner Violence, Psychological Perspectives on
Introversion–Extraversion
Item Response Theory
Law, Psychology and
Lazarus, Richard
Learned Helplessness
Learning versus Performance
LGBTQ+ Romantic Relationships
Lie Detection in a Forensic Context
Life-Span Development
Locus of Control
Loneliness and Health
Mathematical Psychology
Meaning in Life
Mechanisms and Processes of Peer Contagion
Media Violence, Psychological Perspectives on
Mediation Analysis
Memories, Autobiographical
Memories, Flashbulb
Memories, Repressed and Recovered
Memory, False
Memory, Human
Memory, Implicit versus Explicit
Memory in Educational Settings
Memory, Semantic
Meta-Analysis
Metacognition
Metaphor, Psychological Perspectives on
Microaggressions
Military Psychology
Mindfulness and Education
Minnesota Multiphasic Personality Inventory (MMPI)
Money, Psychology of
Moral Conviction
Moral Development
Moral Psychology
Moral Reasoning
Nature versus Nurture Debate in Psychology
Neuroscience of Associative Learning
Nonergodicity in Psychology and Neuroscience
Nonparametric Statistical Analysis in Psychology
Observational (Non-Randomized) Studies
Obsessive-Complusive Disorder (OCD)
Occupational Health Psychology
Olfaction, Human
Operant Conditioning
Optimism and Pessimism
Organizational Justice
Parenting Stress
Parenting Styles
Parents' Beliefs about Children
Path Models
Peace Psychology
Perception, Person
Performance Appraisal
Personality and Health
Personality Disorders
Personality Psychology
Person-Centered and Experiential Psychotherapies: From Car...
Phenomenological Psychology
Placebo Effects in Psychology
Play Behavior
Positive Psychological Capital (PsyCap)
Positive Psychology
Posttraumatic Stress Disorder (PTSD)
Prejudice and Stereotyping
Pretrial Publicity
Prisoner's Dilemma
Prosocial Behavior
Prosocial Spending and Well-Being
Protocol Analysis
Psycholinguistics
Psychological Literacy
Psychological Perspectives on Food and Eating
Psychology, Political
Psychoneuroimmunology
Psychophysics, Visual
Psychotherapy
Psychotic Disorders
Publication Bias in Psychology
Reasoning, Counterfactual
Rehabilitation Psychology
Relationships
Reliability–Contemporary Psychometric Conceptions
Religion, Psychology and
Replication Initiatives in Psychology
Research Methods
Risk Taking
Role of the Expert Witness in Forensic Psychology, The
Sample Size Planning for Statistical Power and Accurate Es...
Schizophrenic Disorders
School Psychology
School Psychology, Counseling Services in
Self, Gender and
Self, Psychology of the
Self-Construal
Self-Control
Self-Deception
Self-Determination Theory
Self-Efficacy
Self-Esteem
Self-Monitoring
Self-Regulation in Educational Settings
Self-Report Tests, Measures, and Inventories in Clinical P...
Sensation Seeking
Sex and Gender
Sexual Minority Parenting
Sexual Orientation
Signal Detection Theory and its Applications
Simpson's Paradox in Psychology
Single People
Single-Case Experimental Designs
Skinner, B.F.
Sleep and Dreaming
Small Groups
Social Class and Social Status
Social Cognition
Social Neuroscience
Social Support
Social Touch and Massage Therapy Research
Somatoform Disorders
Spatial Attention
Sports Psychology
Stanford Prison Experiment (SPE): Icon and Controversy
Stereotype Threat
Stereotypes
Stress and Coping, Psychology of
Subjective Wellbeing Homeostasis
Taste, Psychological Perspectives on
Terror Management Theory
Testing and Assessment
The Concept of Validity in Psychological Assessment
The Neuroscience of Emotion Regulation
The Reasoned Action Approach and the Theories of Reasoned ...
The Weapon Focus Effect in Eyewitness Memory
Theory of Mind
Therapy, Cognitive-Behavioral
Time Perception
Trait Perspective
Trauma Psychology
Twin Studies
Type A Behavior Pattern (Coronary Prone Personality)
Unconscious Processes
Video Games and Violent Content
Virtues and Character Strengths
Women and Science, Technology, Engineering, and Math (STEM...
Women, Psychology of
Work Well-Being
Workforce Training Evaluation
Wundt, Wilhelm
Privacy Policy
Cookie Policy
Legal Notice
Accessibility

[66.249.64.20|185.147.128.134]
185.147.128.134

Innovation at WSU
Directories
Give to WSU
Academic Calendar
A-Z Directory
Calendar of Events
Office Hours
Policies and Procedures
Schedule of Courses
Shocker Store
Student Webmail
Technology HelpDesk
Transfer to WSU
University Libraries

Unit 04: How to Think Critically about Psychological Science

Unit 4: how to think critically about psychological science.

Unit 4: Assignment #1 (due before 11:59 pm Central on Monday September 6) :

Watch Crash Course’s (2014) YouTube, “ Psychological Research . ” Because the narrator of the video speaks quite rapidly, you might need to watch the video at least twice (or use the speed-controller in the settings options on YouTube).
Read Halonen’s (1996) article, “ On Critical Thinking [in Psychology] . ” Note that in Unit 2, we worked on what Halonen refers to as “Practical” critical thinking skills. In this Unit, we will be working on what Halonen refers to as “Methodological” critical thinking skills.
Read the first page of Dewey’s (2007) chapter, “ Critical Thinking [in Psychology] . ”
Read Stafford’s (2014) article, “ What It Means To Be Critical [about Psychological Research] ,” which is more about how to be critical of psychological science than why it’s important to be critical, but Stafford’s article will prepare you for other Assignments in this Unit.
You may write either a Reasons/Arguments Essay OR an Examples Essay.
Remember to begin by jotting down somewhere your three Reasons/Arguments or your three Examples.
Next, you should write your three Reasons/Arguments paragraphs or your three Examples paragraphs.
Then, you should write your Thesis Statement.
Next, write your Introduction Paragraph, including a hook.
The last step is to write your Conclusion Paragraph, in which you restate your Thesis Statement and end with something witty or profound
a Topic Sentence;
three Supporting Sentences; and
a Conclusion Sentence.
Save your essay as PDF and name the file YourLastname_CriticalThinkingEssay.pdf .
Go to the Unit 4: Assignment #1 Discussion Board and make a new Discussion Board post to which you attach your essay, saved as a PDF. Remember to “Attach” your essay’s PDF (don’t embed your file or use use the “File” tool; instead, use the “Attach” tool).

Unit 4: Assignment #2 (due before 11:59 pm Central on Tuesday September 7) :

Read about the first (“Sensationalized Headlines”), second (“Misinterpreted Results”), third (“Conflicts of Interest”), and twelfth (“Non-Peer Reviewed Material”) indicator of bad science in Compound Interest’s (2015) infographic “ A Rough Guide to Spotting Bad Science .”
To see examples of the first (“Sensationalized Headlines”) and twelfth (“Non-Peer Reviewed Material”) indicators of bad science, watch Above the Noise’s (2017) YouTube, “ T op 4 Tips To Spot Bad Science Reporting .”
Read Ossola’s (2017) article, “ Can You Tell If a Health Story Is Total BS? ” Ossola’s indicators of “Check the Label” and “Control the Spin” are like Compound Interest’s “Sensationalized Headlines” indicator; however, Ossola presents a novel indicator “Beware the Animal Study.”
To see examples of these indicators of bad science, watch Last Week Tonight with John Oliver’s (2016) YouTube, “ Scientific Studies .” Warning: John Oliver is a late-night comedian/TV host. Therefore, this video contains adult content, adult language, and extreme irreverence toward a wide swath of people. The video presents numerous examples of bad science indicators; however, if you’d prefer not to watch the video, then please don’t.
“Sensationalized Headlines”
“Misinterpreted Results”
“Non-Peer Reviewed Material”
“Beware the Animal Study”
“Conflicts of Interest”
Be sure to find three different news reports, each of which reports about a different research study , rather than three news reports all of which report about the same research study.
Describe each of the three news reports, preferably each in its own paragraph.
Identify which indicator of bad science characterizes each news report.
Provide for each news report either its URL (using the technique you learned from the Course How To ) or, if a video, its YouTube or Vimeo (using the technique you learned from the Course How To ).

Unit 4: Assignment #3 (due before 11:59 pm Central on Wednesday September 8) :

Watch TEDxDelft’s (2012) YouTube, “ The Danger of Mixing Up Causality and Correlation . ”
Watch PsychU’s (2015) YouTube, “ Correlation vs. Causation – PSY 101 . ”
Because PsychU momentarily confuses the term “hypothesis” with the term “theory,” watch PBS’s (2015) YouTube “ Fact vs. Theory vs. Hypothesis vs. Law … Explained! ”
Make sure you know the meanings of, and differences among, the four terms: Fact, Theory, Hypothesis, and Law. Not only will you will need to know these terms and their differences throughout the rest of this course, but everyone should know these terms and their differences.
Watch AsapScience’s (2017) YouTube, “ This ≠ That .”
Watch Khan Academy’s (2011) YouTube, “ Correlation and Causality . ”
Jot down at least six examples of correlation not proving causation from the videos you watched. One example is the correlation between the amount of ice cream purchased (during each month of the year) and the number of drowning deaths (during each month of the year) not proving that ice cream causes drowning.
Make sure you understand that two variables (e.g., ice cream purchases per month and drowning deaths per month) might both be caused by another variable (e.g., season of the year). That other variable is often called a confounding variable.
Make sure you understand that the correlation between two variables (e.g., pool drownings per year and Nicholas Cage films per year) might simply be due to coincidence.
Make sure you understand that rather than one variable (e.g., skipping breakfast) causing another variable (e.g., obesity), the causation might be reversed.
When you are teaching each person, provide examples of correlations that do not prove causation, using the examples you saw in the videos.
To make sure that each of the three people learned why correlation should not be interpreted as causation, ask each person to tell you another example (an example that you did not tell them) of correlation not proving causation.
Also teach each of the three persons the difference between hypothesis and theory.
describe how you taught the three persons that correlation cannot be interpreted as causation;
state each of the three persons’ initials (e.g., MG) and their approximate age; and
report the examples each person told you of correlations that should not be confused with causation.

Unit 4: Assignment #4 (due before 11:59 pm Central on Thursday September 9) :

To cement your learning about critical thinking and psychological science, read Tesler’s (2016) article, “ Can You Believe It? Seven Questions to Ask About Any Scientific Claim .”
Go to the Unit 4: Assignment #2 and #4 Discussion Board and read all the posts made in Unit 4: Assignment #2 by the other members (or member) of your Chat Group.
If you are in a Chat Group with two other members, and one of the two other Chat Group members hasn’t yet posted their Unit 4: Assignment #2 — and the due date for Unit 4: Assignment #2 has passed — you can choose two studies from the Chat Group member who has already posted their Unit 4: Assignment #2.
If you are in a Chat Group with only one other member , and that other member hasn’t yet posted their Unit 4: Assignment #2 — and the due date for Unit 4: Assignment #2 has passed — you can choose two studies from students who are not in your Chat Group.
Now, pretend that instead of your Chat Group member(s) finding and posting these two studies on our class Discussion Board as examples of bad science, two relatives or acquaintances of yours posted the two studies on Facebook, Twitter, or other social media as recommendations to their friends and followers (of good science).
You are required to make two separate Discussion Board response posts (replies); each response post should be at least 200 words, and each post should be in response to only one of the two studies.
Even if you are replying to the same student, you must make two separate Discussion Board posts.
Each of your two response posts must incorporate what you learned from Tesler’s (2016) article.
Address your two responses not to your Chat Group Member(s) but instead to fictitious people, such as “Dear Aunt Bessie” or “Hey, Freshman Roommate.”

Unit 4: Assignment #5 (due before 11:59 pm Central on Saturday September 11) :

download (to your own computer) and save The Logic of Science’s (no date) Hierarchy of Scientific Evidence graphic (PDF format) ; (Text-Only Word format) , and
read Brunning’s (2015) article, “ A Rough Guide to Types of Scientific Evidence .”
Then, read about some of the most famous psychology case reports in Jarrett’s (2015) article, “ Psychology’s Greatest Case Studies – Digested .”
Think about why it was important for the various scientists who reported these case studies to report these case studies.
Then, read about an example of a randomized controlled study in Fradera’s (2017) article, “ How Much Are Readers Misled by Headlines that Imply Correlational Findings Are Causal? ”
Think about why it was important for these scientists to conduct a randomized controlled study on this topic.
Then, to see an example of a journal article reporting a meta-analysis, read the abstract of Hyde and Lynn’s (1988) article, “ Gender Differences in Verbal Ability: A Meta-Analysis .”
Think about why it was important for these scientists to conduct a meta-analysis on this topic.
Begin by jotting down your three Reasons/Arguments or your three Examples.
Then, write your three Reasons/Arguments Paragraphs or your three Examples Paragraphs.
For each of your three Reasons/Arguments Paragraphs or each of your three Examples Paragraphs, write a Topic Sentence, three Supporting Sentences, and a Conclusion Sentence.
Then, write your essay’s Thesis Statement.
Then, write your essay’s Introduction Paragraph, including a hook.
Then, write your essay’s Conclusion Paragraph, in which you restate your Thesis Statement and end with something witty or profound.
Remember that all five of your paragraphs, your Introduction Paragraph, each of your three Reasons/Arguments Paragraphs or your three Examples Paragraphs, and your Conclusion Paragraph, must have a Topic Sentence, three Supporting Sentences, and a Conclusion Sentence.
Save your essay as a PDF and name the file YourLastname_EvidenceEssay.pdf .
Make a new Discussion Board post to which you attach your essay, saved as a PDF. This is described in the Course How To (under the topic, “How to Save and Attach a Group Text Chat Transcript”).

Unit 4: Assignment #6 (due before 11:59 pm Central on Monday September 13) :

To learn what replication means in research, read CK-12’s (no date) article, “ Replication .”
To get a quick overview of replication courtesy of the NBC comedy TV show, “The Good Place,” read Harnett’s 2019 tweet .
Be sure to notice in the excerpt from Dewey’s article the methodological reasons he gives for why a result might not replicate.
Be sure to read the entire cartoon, frame by frame.
Although it might seem repetitive, the point is to read closely through all 20 of the frames that report the scientists’ results.
Then read the final page’s “Explanation.”
Now that you understand what p-hacking means, read Hobbes’s (2019) tweet about the problems with studies that report a link between “a single food” (e.g., eggs) and “a single health outcome” (e.g., heart disease).
To ensure that you understand the role of chance and statistical probability in producing a result that might not replicate, read Hanna’s (2012) article, “ Why Is Replication So Important? ”
To understand the difference between the term replication and reproduction , read the handout, “ Replication (and Replicability) versus Reproduction (and Reproducibility) . ”
To understand the role of false positives in research, watch Veritasium’s (2016) YouTube, “ Is Most Published Research Wrong? ”
This YouTube is a more complex video than some of the others you’ve watched in this Unit.
Try to understand as much as you can. You’ll have a chance to discuss what you don’t understand in this video with your Chat Group.
If your last name comes first alphabetically in your Chat Group, watch NOVA’s (2017) video “ What Makes Science True ? ”
If your last name comes last alphabetically in your Chat Group, read all the way through Naro’s (2016) comic strip, “ Why Can’t Anyone Replicate the Scientific Studies from Those Eye-Grabbing Headlines? ”
If your last name comes neither first nor last in your Chat Group (or if you are in a Chat Group with only two members), read Carroll’s (2017) article, “ Science Needs a Solution for the Temptation of Positive Results ” and Leyser et al.’s (2017) article, “ The Science ‘Reproducibility Crisis’ – and What Can Be Done about It? ”
Begin by reviewing the articles and videos that everyone in your Chat Group read and watched.
Next, take turns telling the other member(s) of your Chat Group about the article, video, or comic strip that individual Chat Group members read.
identify one statistical (probability) reason ;
identify one researcher motivation ; and
one news media motivation that could lead to the public seeing headlines such as these two conflicting headlines .
propose one solution to the statistical (probability) reason you identified;
propose one solution to the researcher motivation you identified; and
propose one solution to the the news media motivation you identified.
Nominate one member of your Chat Group (who participated in the Chat) to make a post on the Unit 4: Assignment #6 Discussion Board that summarizes your Group Chat in at least 200 words.
Then, this member of the Chat Group needs to make a post on the Unit 4: Assignment #6 Discussion Board and attach the Chat transcript, saved as a PDF, to that Discussion Board post.
Nominate a third member of your Chat Group (who also participated in the Chat) to make another post on the Unit 4: Assignment #6 Discussion Board that states the name of your Chat Group, the names of the Chat Group members who participated the Chat, the date of your Chat, and the start and stop time of your Group Chat.
If only two persons participated in the Chat, then one of those two persons needs to do two of the above three tasks.
Before ending the Group Chat, arrange the date and time for the Group Chat you will need to hold during the next Unit (Unit 5: Assignment #6).
All members of the Chat Group must record a typical Unit entry in their own Course Journal for Unit 4.

Congratulations, you have finished Unit 4! Onward to Unit 5 !

Open-Access Active-Learning Research Methods Course by Morton Ann Gernsbacher, PhD is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License . The materials have been modified to add various ADA-compliant accessibility features, in some cases including alternative text-only versions. Permissions beyond the scope of this license may be available at http://www.gernsbacherlab.org .

An official website of the United States government

The .gov means it’s official. Federal government websites often end in .gov or .mil. Before sharing sensitive information, make sure you’re on a federal government site.

The site is secure. The https:// ensures that you are connecting to the official website and that any information you provide is encrypted and transmitted securely.

Publications
Account settings

Preview improvements coming to the PMC website in October 2024. Learn More or Try it out now .

Advanced Search
Journal List
CBE Life Sci Educ
v.17(1); Spring 2018

Understanding the Complex Relationship between Critical Thinking and Science Reasoning among Undergraduate Thesis Writers

Jason e. dowd.

† Department of Biology, Duke University, Durham, NC 27708

Robert J. Thompson, Jr.

‡ Department of Psychology and Neuroscience, Duke University, Durham, NC 27708

Leslie A. Schiff

§ Department of Microbiology and Immunology, University of Minnesota, Minneapolis, MN 55455

Julie A. Reynolds

Associated data.

This study empirically examines the relationship between students’ critical-thinking skills and scientific reasoning as reflected in undergraduate thesis writing in biology. Writing offers a unique window into studying this relationship, and the findings raise potential implications for instruction.

Developing critical-thinking and scientific reasoning skills are core learning objectives of science education, but little empirical evidence exists regarding the interrelationships between these constructs. Writing effectively fosters students’ development of these constructs, and it offers a unique window into studying how they relate. In this study of undergraduate thesis writing in biology at two universities, we examine how scientific reasoning exhibited in writing (assessed using the Biology Thesis Assessment Protocol) relates to general and specific critical-thinking skills (assessed using the California Critical Thinking Skills Test), and we consider implications for instruction. We find that scientific reasoning in writing is strongly related to inference , while other aspects of science reasoning that emerge in writing (epistemological considerations, writing conventions, etc.) are not significantly related to critical-thinking skills. Science reasoning in writing is not merely a proxy for critical thinking. In linking features of students’ writing to their critical-thinking skills, this study 1) provides a bridge to prior work suggesting that engagement in science writing enhances critical thinking and 2) serves as a foundational step for subsequently determining whether instruction focused explicitly on developing critical-thinking skills (particularly inference ) can actually improve students’ scientific reasoning in their writing.

INTRODUCTION

Critical-thinking and scientific reasoning skills are core learning objectives of science education for all students, regardless of whether or not they intend to pursue a career in science or engineering. Consistent with the view of learning as construction of understanding and meaning ( National Research Council, 2000 ), the pedagogical practice of writing has been found to be effective not only in fostering the development of students’ conceptual and procedural knowledge ( Gerdeman et al. , 2007 ) and communication skills ( Clase et al. , 2010 ), but also scientific reasoning ( Reynolds et al. , 2012 ) and critical-thinking skills ( Quitadamo and Kurtz, 2007 ).

Critical thinking and scientific reasoning are similar but different constructs that include various types of higher-order cognitive processes, metacognitive strategies, and dispositions involved in making meaning of information. Critical thinking is generally understood as the broader construct ( Holyoak and Morrison, 2005 ), comprising an array of cognitive processes and dispostions that are drawn upon differentially in everyday life and across domains of inquiry such as the natural sciences, social sciences, and humanities. Scientific reasoning, then, may be interpreted as the subset of critical-thinking skills (cognitive and metacognitive processes and dispositions) that 1) are involved in making meaning of information in scientific domains and 2) support the epistemological commitment to scientific methodology and paradigm(s).

Although there has been an enduring focus in higher education on promoting critical thinking and reasoning as general or “transferable” skills, research evidence provides increasing support for the view that reasoning and critical thinking are also situational or domain specific ( Beyer et al. , 2013 ). Some researchers, such as Lawson (2010) , present frameworks in which science reasoning is characterized explicitly in terms of critical-thinking skills. There are, however, limited coherent frameworks and empirical evidence regarding either the general or domain-specific interrelationships of scientific reasoning, as it is most broadly defined, and critical-thinking skills.

The Vision and Change in Undergraduate Biology Education Initiative provides a framework for thinking about these constructs and their interrelationship in the context of the core competencies and disciplinary practice they describe ( American Association for the Advancement of Science, 2011 ). These learning objectives aim for undergraduates to “understand the process of science, the interdisciplinary nature of the new biology and how science is closely integrated within society; be competent in communication and collaboration; have quantitative competency and a basic ability to interpret data; and have some experience with modeling, simulation and computational and systems level approaches as well as with using large databases” ( Woodin et al. , 2010 , pp. 71–72). This framework makes clear that science reasoning and critical-thinking skills play key roles in major learning outcomes; for example, “understanding the process of science” requires students to engage in (and be metacognitive about) scientific reasoning, and having the “ability to interpret data” requires critical-thinking skills. To help students better achieve these core competencies, we must better understand the interrelationships of their composite parts. Thus, the next step is to determine which specific critical-thinking skills are drawn upon when students engage in science reasoning in general and with regard to the particular scientific domain being studied. Such a determination could be applied to improve science education for both majors and nonmajors through pedagogical approaches that foster critical-thinking skills that are most relevant to science reasoning.

Writing affords one of the most effective means for making thinking visible ( Reynolds et al. , 2012 ) and learning how to “think like” and “write like” disciplinary experts ( Meizlish et al. , 2013 ). As a result, student writing affords the opportunities to both foster and examine the interrelationship of scientific reasoning and critical-thinking skills within and across disciplinary contexts. The purpose of this study was to better understand the relationship between students’ critical-thinking skills and scientific reasoning skills as reflected in the genre of undergraduate thesis writing in biology departments at two research universities, the University of Minnesota and Duke University.

In the following subsections, we discuss in greater detail the constructs of scientific reasoning and critical thinking, as well as the assessment of scientific reasoning in students’ thesis writing. In subsequent sections, we discuss our study design, findings, and the implications for enhancing educational practices.

Critical Thinking

The advances in cognitive science in the 21st century have increased our understanding of the mental processes involved in thinking and reasoning, as well as memory, learning, and problem solving. Critical thinking is understood to include both a cognitive dimension and a disposition dimension (e.g., reflective thinking) and is defined as “purposeful, self-regulatory judgment which results in interpretation, analysis, evaluation, and inference, as well as explanation of the evidential, conceptual, methodological, criteriological, or contextual considerations upon which that judgment is based” ( Facione, 1990, p. 3 ). Although various other definitions of critical thinking have been proposed, researchers have generally coalesced on this consensus: expert view ( Blattner and Frazier, 2002 ; Condon and Kelly-Riley, 2004 ; Bissell and Lemons, 2006 ; Quitadamo and Kurtz, 2007 ) and the corresponding measures of critical-thinking skills ( August, 2016 ; Stephenson and Sadler-McKnight, 2016 ).

Both the cognitive skills and dispositional components of critical thinking have been recognized as important to science education ( Quitadamo and Kurtz, 2007 ). Empirical research demonstrates that specific pedagogical practices in science courses are effective in fostering students’ critical-thinking skills. Quitadamo and Kurtz (2007) found that students who engaged in a laboratory writing component in the context of a general education biology course significantly improved their overall critical-thinking skills (and their analytical and inference skills, in particular), whereas students engaged in a traditional quiz-based laboratory did not improve their critical-thinking skills. In related work, Quitadamo et al. (2008) found that a community-based inquiry experience, involving inquiry, writing, research, and analysis, was associated with improved critical thinking in a biology course for nonmajors, compared with traditionally taught sections. In both studies, students who exhibited stronger presemester critical-thinking skills exhibited stronger gains, suggesting that “students who have not been explicitly taught how to think critically may not reach the same potential as peers who have been taught these skills” ( Quitadamo and Kurtz, 2007 , p. 151).

Recently, Stephenson and Sadler-McKnight (2016) found that first-year general chemistry students who engaged in a science writing heuristic laboratory, which is an inquiry-based, writing-to-learn approach to instruction ( Hand and Keys, 1999 ), had significantly greater gains in total critical-thinking scores than students who received traditional laboratory instruction. Each of the four components—inquiry, writing, collaboration, and reflection—have been linked to critical thinking ( Stephenson and Sadler-McKnight, 2016 ). Like the other studies, this work highlights the value of targeting critical-thinking skills and the effectiveness of an inquiry-based, writing-to-learn approach to enhance critical thinking. Across studies, authors advocate adopting critical thinking as the course framework ( Pukkila, 2004 ) and developing explicit examples of how critical thinking relates to the scientific method ( Miri et al. , 2007 ).

In these examples, the important connection between writing and critical thinking is highlighted by the fact that each intervention involves the incorporation of writing into science, technology, engineering, and mathematics education (either alone or in combination with other pedagogical practices). However, critical-thinking skills are not always the primary learning outcome; in some contexts, scientific reasoning is the primary outcome that is assessed.

Scientific Reasoning

Scientific reasoning is a complex process that is broadly defined as “the skills involved in inquiry, experimentation, evidence evaluation, and inference that are done in the service of conceptual change or scientific understanding” ( Zimmerman, 2007 , p. 172). Scientific reasoning is understood to include both conceptual knowledge and the cognitive processes involved with generation of hypotheses (i.e., inductive processes involved in the generation of hypotheses and the deductive processes used in the testing of hypotheses), experimentation strategies, and evidence evaluation strategies. These dimensions are interrelated, in that “experimentation and inference strategies are selected based on prior conceptual knowledge of the domain” ( Zimmerman, 2000 , p. 139). Furthermore, conceptual and procedural knowledge and cognitive process dimensions can be general and domain specific (or discipline specific).

With regard to conceptual knowledge, attention has been focused on the acquisition of core methodological concepts fundamental to scientists’ causal reasoning and metacognitive distancing (or decontextualized thinking), which is the ability to reason independently of prior knowledge or beliefs ( Greenhoot et al. , 2004 ). The latter involves what Kuhn and Dean (2004) refer to as the coordination of theory and evidence, which requires that one question existing theories (i.e., prior knowledge and beliefs), seek contradictory evidence, eliminate alternative explanations, and revise one’s prior beliefs in the face of contradictory evidence. Kuhn and colleagues (2008) further elaborate that scientific thinking requires “a mature understanding of the epistemological foundations of science, recognizing scientific knowledge as constructed by humans rather than simply discovered in the world,” and “the ability to engage in skilled argumentation in the scientific domain, with an appreciation of argumentation as entailing the coordination of theory and evidence” ( Kuhn et al. , 2008 , p. 435). “This approach to scientific reasoning not only highlights the skills of generating and evaluating evidence-based inferences, but also encompasses epistemological appreciation of the functions of evidence and theory” ( Ding et al. , 2016 , p. 616). Evaluating evidence-based inferences involves epistemic cognition, which Moshman (2015) defines as the subset of metacognition that is concerned with justification, truth, and associated forms of reasoning. Epistemic cognition is both general and domain specific (or discipline specific; Moshman, 2015 ).

There is empirical support for the contributions of both prior knowledge and an understanding of the epistemological foundations of science to scientific reasoning. In a study of undergraduate science students, advanced scientific reasoning was most often accompanied by accurate prior knowledge as well as sophisticated epistemological commitments; additionally, for students who had comparable levels of prior knowledge, skillful reasoning was associated with a strong epistemological commitment to the consistency of theory with evidence ( Zeineddin and Abd-El-Khalick, 2010 ). These findings highlight the importance of the need for instructional activities that intentionally help learners develop sophisticated epistemological commitments focused on the nature of knowledge and the role of evidence in supporting knowledge claims ( Zeineddin and Abd-El-Khalick, 2010 ).

Scientific Reasoning in Students’ Thesis Writing

Pedagogical approaches that incorporate writing have also focused on enhancing scientific reasoning. Many rubrics have been developed to assess aspects of scientific reasoning in written artifacts. For example, Timmerman and colleagues (2011) , in the course of describing their own rubric for assessing scientific reasoning, highlight several examples of scientific reasoning assessment criteria ( Haaga, 1993 ; Tariq et al. , 1998 ; Topping et al. , 2000 ; Kelly and Takao, 2002 ; Halonen et al. , 2003 ; Willison and O’Regan, 2007 ).

At both the University of Minnesota and Duke University, we have focused on the genre of the undergraduate honors thesis as the rhetorical context in which to study and improve students’ scientific reasoning and writing. We view the process of writing an undergraduate honors thesis as a form of professional development in the sciences (i.e., a way of engaging students in the practices of a community of discourse). We have found that structured courses designed to scaffold the thesis-writing process and promote metacognition can improve writing and reasoning skills in biology, chemistry, and economics ( Reynolds and Thompson, 2011 ; Dowd et al. , 2015a , b ). In the context of this prior work, we have defined scientific reasoning in writing as the emergent, underlying construct measured across distinct aspects of students’ written discussion of independent research in their undergraduate theses.

The Biology Thesis Assessment Protocol (BioTAP) was developed at Duke University as a tool for systematically guiding students and faculty through a “draft–feedback–revision” writing process, modeled after professional scientific peer-review processes ( Reynolds et al. , 2009 ). BioTAP includes activities and worksheets that allow students to engage in critical peer review and provides detailed descriptions, presented as rubrics, of the questions (i.e., dimensions, shown in Table 1 ) upon which such review should focus. Nine rubric dimensions focus on communication to the broader scientific community, and four rubric dimensions focus on the accuracy and appropriateness of the research. These rubric dimensions provide criteria by which the thesis is assessed, and therefore allow BioTAP to be used as an assessment tool as well as a teaching resource ( Reynolds et al. , 2009 ). Full details are available at www.science-writing.org/biotap.html .

Theses assessment protocol dimensions

In previous work, we have used BioTAP to quantitatively assess students’ undergraduate honors theses and explore the relationship between thesis-writing courses (or specific interventions within the courses) and the strength of students’ science reasoning in writing across different science disciplines: biology ( Reynolds and Thompson, 2011 ); chemistry ( Dowd et al. , 2015b ); and economics ( Dowd et al. , 2015a ). We have focused exclusively on the nine dimensions related to reasoning and writing (questions 1–9), as the other four dimensions (questions 10–13) require topic-specific expertise and are intended to be used by the student’s thesis supervisor.

Beyond considering individual dimensions, we have investigated whether meaningful constructs underlie students’ thesis scores. We conducted exploratory factor analysis of students’ theses in biology, economics, and chemistry and found one dominant underlying factor in each discipline; we termed the factor “scientific reasoning in writing” ( Dowd et al. , 2015a , b , 2016 ). That is, each of the nine dimensions could be understood as reflecting, in different ways and to different degrees, the construct of scientific reasoning in writing. The findings indicated evidence of both general and discipline-specific components to scientific reasoning in writing that relate to epistemic beliefs and paradigms, in keeping with broader ideas about science reasoning discussed earlier. Specifically, scientific reasoning in writing is more strongly associated with formulating a compelling argument for the significance of the research in the context of current literature in biology, making meaning regarding the implications of the findings in chemistry, and providing an organizational framework for interpreting the thesis in economics. We suggested that instruction, whether occurring in writing studios or in writing courses to facilitate thesis preparation, should attend to both components.

Research Question and Study Design

The genre of thesis writing combines the pedagogies of writing and inquiry found to foster scientific reasoning ( Reynolds et al. , 2012 ) and critical thinking ( Quitadamo and Kurtz, 2007 ; Quitadamo et al. , 2008 ; Stephenson and Sadler-McKnight, 2016 ). However, there is no empirical evidence regarding the general or domain-specific interrelationships of scientific reasoning and critical-thinking skills, particularly in the rhetorical context of the undergraduate thesis. The BioTAP studies discussed earlier indicate that the rubric-based assessment produces evidence of scientific reasoning in the undergraduate thesis, but it was not designed to foster or measure critical thinking. The current study was undertaken to address the research question: How are students’ critical-thinking skills related to scientific reasoning as reflected in the genre of undergraduate thesis writing in biology? Determining these interrelationships could guide efforts to enhance students’ scientific reasoning and writing skills through focusing instruction on specific critical-thinking skills as well as disciplinary conventions.

To address this research question, we focused on undergraduate thesis writers in biology courses at two institutions, Duke University and the University of Minnesota, and examined the extent to which students’ scientific reasoning in writing, assessed in the undergraduate thesis using BioTAP, corresponds to students’ critical-thinking skills, assessed using the California Critical Thinking Skills Test (CCTST; August, 2016 ).

Study Sample

The study sample was composed of students enrolled in courses designed to scaffold the thesis-writing process in the Department of Biology at Duke University and the College of Biological Sciences at the University of Minnesota. Both courses complement students’ individual work with research advisors. The course is required for thesis writers at the University of Minnesota and optional for writers at Duke University. Not all students are required to complete a thesis, though it is required for students to graduate with honors; at the University of Minnesota, such students are enrolled in an honors program within the college. In total, 28 students were enrolled in the course at Duke University and 44 students were enrolled in the course at the University of Minnesota. Of those students, two students did not consent to participate in the study; additionally, five students did not validly complete the CCTST (i.e., attempted fewer than 60% of items or completed the test in less than 15 minutes). Thus, our overall rate of valid participation is 90%, with 27 students from Duke University and 38 students from the University of Minnesota. We found no statistically significant differences in thesis assessment between students with valid CCTST scores and invalid CCTST scores. Therefore, we focus on the 65 students who consented to participate and for whom we have complete and valid data in most of this study. Additionally, in asking students for their consent to participate, we allowed them to choose whether to provide or decline access to academic and demographic background data. Of the 65 students who consented to participate, 52 students granted access to such data. Therefore, for additional analyses involving academic and background data, we focus on the 52 students who consented. We note that the 13 students who participated but declined to share additional data performed slightly lower on the CCTST than the 52 others (perhaps suggesting that they differ by other measures, but we cannot determine this with certainty). Among the 52 students, 60% identified as female and 10% identified as being from underrepresented ethnicities.

In both courses, students completed the CCTST online, either in class or on their own, late in the Spring 2016 semester. This is the same assessment that was used in prior studies of critical thinking ( Quitadamo and Kurtz, 2007 ; Quitadamo et al. , 2008 ; Stephenson and Sadler-McKnight, 2016 ). It is “an objective measure of the core reasoning skills needed for reflective decision making concerning what to believe or what to do” ( Insight Assessment, 2016a ). In the test, students are asked to read and consider information as they answer multiple-choice questions. The questions are intended to be appropriate for all users, so there is no expectation of prior disciplinary knowledge in biology (or any other subject). Although actual test items are protected, sample items are available on the Insight Assessment website ( Insight Assessment, 2016b ). We have included one sample item in the Supplemental Material.

The CCTST is based on a consensus definition of critical thinking, measures cognitive and metacognitive skills associated with critical thinking, and has been evaluated for validity and reliability at the college level ( August, 2016 ; Stephenson and Sadler-McKnight, 2016 ). In addition to providing overall critical-thinking score, the CCTST assesses seven dimensions of critical thinking: analysis, interpretation, inference, evaluation, explanation, induction, and deduction. Scores on each dimension are calculated based on students’ performance on items related to that dimension. Analysis focuses on identifying assumptions, reasons, and claims and examining how they interact to form arguments. Interpretation, related to analysis, focuses on determining the precise meaning and significance of information. Inference focuses on drawing conclusions from reasons and evidence. Evaluation focuses on assessing the credibility of sources of information and claims they make. Explanation, related to evaluation, focuses on describing the evidence, assumptions, or rationale for beliefs and conclusions. Induction focuses on drawing inferences about what is probably true based on evidence. Deduction focuses on drawing conclusions about what must be true when the context completely determines the outcome. These are not independent dimensions; the fact that they are related supports their collective interpretation as critical thinking. Together, the CCTST dimensions provide a basis for evaluating students’ overall strength in using reasoning to form reflective judgments about what to believe or what to do ( August, 2016 ). Each of the seven dimensions and the overall CCTST score are measured on a scale of 0–100, where higher scores indicate superior performance. Scores correspond to superior (86–100), strong (79–85), moderate (70–78), weak (63–69), or not manifested (62 and below) skills.

Scientific Reasoning in Writing

At the end of the semester, students’ final, submitted undergraduate theses were assessed using BioTAP, which consists of nine rubric dimensions that focus on communication to the broader scientific community and four additional dimensions that focus on the exhibition of topic-specific expertise ( Reynolds et al. , 2009 ). These dimensions, framed as questions, are displayed in Table 1 .

Student theses were assessed on questions 1–9 of BioTAP using the same procedures described in previous studies ( Reynolds and Thompson, 2011 ; Dowd et al. , 2015a , b ). In this study, six raters were trained in the valid, reliable use of BioTAP rubrics. Each dimension was rated on a five-point scale: 1 indicates the dimension is missing, incomplete, or below acceptable standards; 3 indicates that the dimension is adequate but not exhibiting mastery; and 5 indicates that the dimension is excellent and exhibits mastery (intermediate ratings of 2 and 4 are appropriate when different parts of the thesis make a single category challenging). After training, two raters independently assessed each thesis and then discussed their independent ratings with one another to form a consensus rating. The consensus score is not an average score, but rather an agreed-upon, discussion-based score. On a five-point scale, raters independently assessed dimensions to be within 1 point of each other 82.4% of the time before discussion and formed consensus ratings 100% of the time after discussion.

In this study, we consider both categorical (mastery/nonmastery, where a score of 5 corresponds to mastery) and numerical treatments of individual BioTAP scores to better relate the manifestation of critical thinking in BioTAP assessment to all of the prior studies. For comprehensive/cumulative measures of BioTAP, we focus on the partial sum of questions 1–5, as these questions relate to higher-order scientific reasoning (whereas questions 6–9 relate to mid- and lower-order writing mechanics [ Reynolds et al. , 2009 ]), and the factor scores (i.e., numerical representations of the extent to which each student exhibits the underlying factor), which are calculated from the factor loadings published by Dowd et al. (2016) . We do not focus on questions 6–9 individually in statistical analyses, because we do not expect critical-thinking skills to relate to mid- and lower-order writing skills.

The final, submitted thesis reflects the student’s writing, the student’s scientific reasoning, the quality of feedback provided to the student by peers and mentors, and the student’s ability to incorporate that feedback into his or her work. Therefore, our assessment is not the same as an assessment of unpolished, unrevised samples of students’ written work. While one might imagine that such an unpolished sample may be more strongly correlated with critical-thinking skills measured by the CCTST, we argue that the complete, submitted thesis, assessed using BioTAP, is ultimately a more appropriate reflection of how students exhibit science reasoning in the scientific community.

Statistical Analyses

We took several steps to analyze the collected data. First, to provide context for subsequent interpretations, we generated descriptive statistics for the CCTST scores of the participants based on the norms for undergraduate CCTST test takers. To determine the strength of relationships among CCTST dimensions (including overall score) and the BioTAP dimensions, partial-sum score (questions 1–5), and factor score, we calculated Pearson’s correlations for each pair of measures. To examine whether falling on one side of the nonmastery/mastery threshold (as opposed to a linear scale of performance) was related to critical thinking, we grouped BioTAP dimensions into categories (mastery/nonmastery) and conducted Student’s t tests to compare the means scores of the two groups on each of the seven dimensions and overall score of the CCTST. Finally, for the strongest relationship that emerged, we included additional academic and background variables as covariates in multiple linear-regression analysis to explore questions about how much observed relationships between critical-thinking skills and science reasoning in writing might be explained by variation in these other factors.

Although BioTAP scores represent discreet, ordinal bins, the five-point scale is intended to capture an underlying continuous construct (from inadequate to exhibiting mastery). It has been argued that five categories is an appropriate cutoff for treating ordinal variables as pseudo-continuous ( Rhemtulla et al. , 2012 )—and therefore using continuous-variable statistical methods (e.g., Pearson’s correlations)—as long as the underlying assumption that ordinal scores are linearly distributed is valid. Although we have no way to statistically test this assumption, we interpret adequate scores to be approximately halfway between inadequate and mastery scores, resulting in a linear scale. In part because this assumption is subject to disagreement, we also consider and interpret a categorical (mastery/nonmastery) treatment of BioTAP variables.

We corrected for multiple comparisons using the Holm-Bonferroni method ( Holm, 1979 ). At the most general level, where we consider the single, comprehensive measures for BioTAP (partial-sum and factor score) and the CCTST (overall score), there is no need to correct for multiple comparisons, because the multiple, individual dimensions are collapsed into single dimensions. When we considered individual CCTST dimensions in relation to comprehensive measures for BioTAP, we accounted for seven comparisons; similarly, when we considered individual dimensions of BioTAP in relation to overall CCTST score, we accounted for five comparisons. When all seven CCTST and five BioTAP dimensions were examined individually and without prior knowledge, we accounted for 35 comparisons; such a rigorous threshold is likely to reject weak and moderate relationships, but it is appropriate if there are no specific pre-existing hypotheses. All p values are presented in tables for complete transparency, and we carefully consider the implications of our interpretation of these data in the Discussion section.

CCTST scores for students in this sample ranged from the 39th to 99th percentile of the general population of undergraduate CCTST test takers (mean percentile = 84.3, median = 85th percentile; Table 2 ); these percentiles reflect overall scores that range from moderate to superior. Scores on individual dimensions and overall scores were sufficiently normal and far enough from the ceiling of the scale to justify subsequent statistical analyses.

Descriptive statistics of CCTST dimensions a

a Scores correspond to superior (86–100), strong (79–85), moderate (70–78), weak (63–69), or not manifested (62 and lower) skills.

The Pearson’s correlations between students’ cumulative scores on BioTAP (the factor score based on loadings published by Dowd et al. , 2016 , and the partial sum of scores on questions 1–5) and students’ overall scores on the CCTST are presented in Table 3 . We found that the partial-sum measure of BioTAP was significantly related to the overall measure of critical thinking ( r = 0.27, p = 0.03), while the BioTAP factor score was marginally related to overall CCTST ( r = 0.24, p = 0.05). When we looked at relationships between comprehensive BioTAP measures and scores for individual dimensions of the CCTST ( Table 3 ), we found significant positive correlations between the both BioTAP partial-sum and factor scores and CCTST inference ( r = 0.45, p < 0.001, and r = 0.41, p < 0.001, respectively). Although some other relationships have p values below 0.05 (e.g., the correlations between BioTAP partial-sum scores and CCTST induction and interpretation scores), they are not significant when we correct for multiple comparisons.

Correlations between dimensions of CCTST and dimensions of BioTAP a

a In each cell, the top number is the correlation, and the bottom, italicized number is the associated p value. Correlations that are statistically significant after correcting for multiple comparisons are shown in bold.

b This is the partial sum of BioTAP scores on questions 1–5.

c This is the factor score calculated from factor loadings published by Dowd et al. (2016) .

When we expanded comparisons to include all 35 potential correlations among individual BioTAP and CCTST dimensions—and, accordingly, corrected for 35 comparisons—we did not find any additional statistically significant relationships. The Pearson’s correlations between students’ scores on each dimension of BioTAP and students’ scores on each dimension of the CCTST range from −0.11 to 0.35 ( Table 3 ); although the relationship between discussion of implications (BioTAP question 5) and inference appears to be relatively large ( r = 0.35), it is not significant ( p = 0.005; the Holm-Bonferroni cutoff is 0.00143). We found no statistically significant relationships between BioTAP questions 6–9 and CCTST dimensions (unpublished data), regardless of whether we correct for multiple comparisons.

The results of Student’s t tests comparing scores on each dimension of the CCTST of students who exhibit mastery with those of students who do not exhibit mastery on each dimension of BioTAP are presented in Table 4 . Focusing first on the overall CCTST scores, we found that the difference between those who exhibit mastery and those who do not in discussing implications of results (BioTAP question 5) is statistically significant ( t = 2.73, p = 0.008, d = 0.71). When we expanded t tests to include all 35 comparisons—and, like above, corrected for 35 comparisons—we found a significant difference in inference scores between students who exhibit mastery on question 5 and students who do not ( t = 3.41, p = 0.0012, d = 0.88), as well as a marginally significant difference in these students’ induction scores ( t = 3.26, p = 0.0018, d = 0.84; the Holm-Bonferroni cutoff is p = 0.00147). Cohen’s d effect sizes, which reveal the strength of the differences for statistically significant relationships, range from 0.71 to 0.88.

The t statistics and effect sizes of differences in dimensions of CCTST across dimensions of BioTAP a

a In each cell, the top number is the t statistic for each comparison, and the middle, italicized number is the associated p value. The bottom number is the effect size. Correlations that are statistically significant after correcting for multiple comparisons are shown in bold.

Finally, we more closely examined the strongest relationship that we observed, which was between the CCTST dimension of inference and the BioTAP partial-sum composite score (shown in Table 3 ), using multiple regression analysis ( Table 5 ). Focusing on the 52 students for whom we have background information, we looked at the simple relationship between BioTAP and inference (model 1), a robust background model including multiple covariates that one might expect to explain some part of the variation in BioTAP (model 2), and a combined model including all variables (model 3). As model 3 shows, the covariates explain very little variation in BioTAP scores, and the relationship between inference and BioTAP persists even in the presence of all of the covariates.

Partial sum (questions 1–5) of BioTAP scores ( n = 52)

** p < 0.01.

*** p < 0.001.

The aim of this study was to examine the extent to which the various components of scientific reasoning—manifested in writing in the genre of undergraduate thesis and assessed using BioTAP—draw on general and specific critical-thinking skills (assessed using CCTST) and to consider the implications for educational practices. Although science reasoning involves critical-thinking skills, it also relates to conceptual knowledge and the epistemological foundations of science disciplines ( Kuhn et al. , 2008 ). Moreover, science reasoning in writing , captured in students’ undergraduate theses, reflects habits, conventions, and the incorporation of feedback that may alter evidence of individuals’ critical-thinking skills. Our findings, however, provide empirical evidence that cumulative measures of science reasoning in writing are nonetheless related to students’ overall critical-thinking skills ( Table 3 ). The particularly significant roles of inference skills ( Table 3 ) and the discussion of implications of results (BioTAP question 5; Table 4 ) provide a basis for more specific ideas about how these constructs relate to one another and what educational interventions may have the most success in fostering these skills.

Our results build on previous findings. The genre of thesis writing combines pedagogies of writing and inquiry found to foster scientific reasoning ( Reynolds et al. , 2012 ) and critical thinking ( Quitadamo and Kurtz, 2007 ; Quitadamo et al. , 2008 ; Stephenson and Sadler-McKnight, 2016 ). Quitadamo and Kurtz (2007) reported that students who engaged in a laboratory writing component in a general education biology course significantly improved their inference and analysis skills, and Quitadamo and colleagues (2008) found that participation in a community-based inquiry biology course (that included a writing component) was associated with significant gains in students’ inference and evaluation skills. The shared focus on inference is noteworthy, because these prior studies actually differ from the current study; the former considered critical-thinking skills as the primary learning outcome of writing-focused interventions, whereas the latter focused on emergent links between two learning outcomes (science reasoning in writing and critical thinking). In other words, inference skills are impacted by writing as well as manifested in writing.

Inference focuses on drawing conclusions from argument and evidence. According to the consensus definition of critical thinking, the specific skill of inference includes several processes: querying evidence, conjecturing alternatives, and drawing conclusions. All of these activities are central to the independent research at the core of writing an undergraduate thesis. Indeed, a critical part of what we call “science reasoning in writing” might be characterized as a measure of students’ ability to infer and make meaning of information and findings. Because the cumulative BioTAP measures distill underlying similarities and, to an extent, suppress unique aspects of individual dimensions, we argue that it is appropriate to relate inference to scientific reasoning in writing . Even when we control for other potentially relevant background characteristics, the relationship is strong ( Table 5 ).

In taking the complementary view and focusing on BioTAP, when we compared students who exhibit mastery with those who do not, we found that the specific dimension of “discussing the implications of results” (question 5) differentiates students’ performance on several critical-thinking skills. To achieve mastery on this dimension, students must make connections between their results and other published studies and discuss the future directions of the research; in short, they must demonstrate an understanding of the bigger picture. The specific relationship between question 5 and inference is the strongest observed among all individual comparisons. Altogether, perhaps more than any other BioTAP dimension, this aspect of students’ writing provides a clear view of the role of students’ critical-thinking skills (particularly inference and, marginally, induction) in science reasoning.

While inference and discussion of implications emerge as particularly strongly related dimensions in this work, we note that the strongest contribution to “science reasoning in writing in biology,” as determined through exploratory factor analysis, is “argument for the significance of research” (BioTAP question 2, not question 5; Dowd et al. , 2016 ). Question 2 is not clearly related to critical-thinking skills. These findings are not contradictory, but rather suggest that the epistemological and disciplinary-specific aspects of science reasoning that emerge in writing through BioTAP are not completely aligned with aspects related to critical thinking. In other words, science reasoning in writing is not simply a proxy for those critical-thinking skills that play a role in science reasoning.

In a similar vein, the content-related, epistemological aspects of science reasoning, as well as the conventions associated with writing the undergraduate thesis (including feedback from peers and revision), may explain the lack of significant relationships between some science reasoning dimensions and some critical-thinking skills that might otherwise seem counterintuitive (e.g., BioTAP question 2, which relates to making an argument, and the critical-thinking skill of argument). It is possible that an individual’s critical-thinking skills may explain some variation in a particular BioTAP dimension, but other aspects of science reasoning and practice exert much stronger influence. Although these relationships do not emerge in our analyses, the lack of significant correlation does not mean that there is definitively no correlation. Correcting for multiple comparisons suppresses type 1 error at the expense of exacerbating type 2 error, which, combined with the limited sample size, constrains statistical power and makes weak relationships more difficult to detect. Ultimately, though, the relationships that do emerge highlight places where individuals’ distinct critical-thinking skills emerge most coherently in thesis assessment, which is why we are particularly interested in unpacking those relationships.

We recognize that, because only honors students submit theses at these institutions, this study sample is composed of a selective subset of the larger population of biology majors. Although this is an inherent limitation of focusing on thesis writing, links between our findings and results of other studies (with different populations) suggest that observed relationships may occur more broadly. The goal of improved science reasoning and critical thinking is shared among all biology majors, particularly those engaged in capstone research experiences. So while the implications of this work most directly apply to honors thesis writers, we provisionally suggest that all students could benefit from further study of them.

There are several important implications of this study for science education practices. Students’ inference skills relate to the understanding and effective application of scientific content. The fact that we find no statistically significant relationships between BioTAP questions 6–9 and CCTST dimensions suggests that such mid- to lower-order elements of BioTAP ( Reynolds et al. , 2009 ), which tend to be more structural in nature, do not focus on aspects of the finished thesis that draw strongly on critical thinking. In keeping with prior analyses ( Reynolds and Thompson, 2011 ; Dowd et al. , 2016 ), these findings further reinforce the notion that disciplinary instructors, who are most capable of teaching and assessing scientific reasoning and perhaps least interested in the more mechanical aspects of writing, may nonetheless be best suited to effectively model and assess students’ writing.

The goal of the thesis writing course at both Duke University and the University of Minnesota is not merely to improve thesis scores but to move students’ writing into the category of mastery across BioTAP dimensions. Recognizing that students with differing critical-thinking skills (particularly inference) are more or less likely to achieve mastery in the undergraduate thesis (particularly in discussing implications [question 5]) is important for developing and testing targeted pedagogical interventions to improve learning outcomes for all students.

The competencies characterized by the Vision and Change in Undergraduate Biology Education Initiative provide a general framework for recognizing that science reasoning and critical-thinking skills play key roles in major learning outcomes of science education. Our findings highlight places where science reasoning–related competencies (like “understanding the process of science”) connect to critical-thinking skills and places where critical thinking–related competencies might be manifested in scientific products (such as the ability to discuss implications in scientific writing). We encourage broader efforts to build empirical connections between competencies and pedagogical practices to further improve science education.

One specific implication of this work for science education is to focus on providing opportunities for students to develop their critical-thinking skills (particularly inference). Of course, as this correlational study is not designed to test causality, we do not claim that enhancing students’ inference skills will improve science reasoning in writing. However, as prior work shows that science writing activities influence students’ inference skills ( Quitadamo and Kurtz, 2007 ; Quitadamo et al. , 2008 ), there is reason to test such a hypothesis. Nevertheless, the focus must extend beyond inference as an isolated skill; rather, it is important to relate inference to the foundations of the scientific method ( Miri et al. , 2007 ) in terms of the epistemological appreciation of the functions and coordination of evidence ( Kuhn and Dean, 2004 ; Zeineddin and Abd-El-Khalick, 2010 ; Ding et al. , 2016 ) and disciplinary paradigms of truth and justification ( Moshman, 2015 ).

Although this study is limited to the domain of biology at two institutions with a relatively small number of students, the findings represent a foundational step in the direction of achieving success with more integrated learning outcomes. Hopefully, it will spur greater interest in empirically grounding discussions of the constructs of scientific reasoning and critical-thinking skills.

This study contributes to the efforts to improve science education, for both majors and nonmajors, through an empirically driven analysis of the relationships between scientific reasoning reflected in the genre of thesis writing and critical-thinking skills. This work is rooted in the usefulness of BioTAP as a method 1) to facilitate communication and learning and 2) to assess disciplinary-specific and general dimensions of science reasoning. The findings support the important role of the critical-thinking skill of inference in scientific reasoning in writing, while also highlighting ways in which other aspects of science reasoning (epistemological considerations, writing conventions, etc.) are not significantly related to critical thinking. Future research into the impact of interventions focused on specific critical-thinking skills (i.e., inference) for improved science reasoning in writing will build on this work and its implications for science education.

Supplementary Material

Acknowledgments.

We acknowledge the contributions of Kelaine Haas and Alexander Motten to the implementation and collection of data. We also thank Mine Çetinkaya-Rundel for her insights regarding our statistical analyses. This research was funded by National Science Foundation award DUE-1525602.

American Association for the Advancement of Science. (2011). Vision and change in undergraduate biology education: A call to action . Washington, DC: Retrieved September 26, 2017, from https://visionandchange.org/files/2013/11/aaas-VISchange-web1113.pdf . [ Google Scholar ]
August D. (2016). California Critical Thinking Skills Test user manual and resource guide . San Jose: Insight Assessment/California Academic Press. [ Google Scholar ]
Beyer C. H., Taylor E., Gillmore G. M. (2013). Inside the undergraduate teaching experience: The University of Washington’s growth in faculty teaching study . Albany, NY: SUNY Press. [ Google Scholar ]
Bissell A. N., Lemons P. P. (2006). A new method for assessing critical thinking in the classroom . BioScience , ( 1 ), 66–72. https://doi.org/10.1641/0006-3568(2006)056[0066:ANMFAC]2.0.CO;2 . [ Google Scholar ]
Blattner N. H., Frazier C. L. (2002). Developing a performance-based assessment of students’ critical thinking skills . Assessing Writing , ( 1 ), 47–64. [ Google Scholar ]
Clase K. L., Gundlach E., Pelaez N. J. (2010). Calibrated peer review for computer-assisted learning of biological research competencies . Biochemistry and Molecular Biology Education , ( 5 ), 290–295. [ PubMed ] [ Google Scholar ]
Condon W., Kelly-Riley D. (2004). Assessing and teaching what we value: The relationship between college-level writing and critical thinking abilities . Assessing Writing , ( 1 ), 56–75. https://doi.org/10.1016/j.asw.2004.01.003 . [ Google Scholar ]
Ding L., Wei X., Liu X. (2016). Variations in university students’ scientific reasoning skills across majors, years, and types of institutions . Research in Science Education , ( 5 ), 613–632. https://doi.org/10.1007/s11165-015-9473-y . [ Google Scholar ]
Dowd J. E., Connolly M. P., Thompson R. J., Jr., Reynolds J. A. (2015a). Improved reasoning in undergraduate writing through structured workshops . Journal of Economic Education , ( 1 ), 14–27. https://doi.org/10.1080/00220485.2014.978924 . [ Google Scholar ]
Dowd J. E., Roy C. P., Thompson R. J., Jr., Reynolds J. A. (2015b). “On course” for supporting expanded participation and improving scientific reasoning in undergraduate thesis writing . Journal of Chemical Education , ( 1 ), 39–45. https://doi.org/10.1021/ed500298r . [ Google Scholar ]
Dowd J. E., Thompson R. J., Jr., Reynolds J. A. (2016). Quantitative genre analysis of undergraduate theses: Uncovering different ways of writing and thinking in science disciplines . WAC Journal , , 36–51. [ Google Scholar ]
Facione P. A. (1990). Critical thinking: a statement of expert consensus for purposes of educational assessment and instruction. Research findings and recommendations . Newark, DE: American Philosophical Association; Retrieved September 26, 2017, from https://philpapers.org/archive/FACCTA.pdf . [ Google Scholar ]
Gerdeman R. D., Russell A. A., Worden K. J., Gerdeman R. D., Russell A. A., Worden K. J. (2007). Web-based student writing and reviewing in a large biology lecture course . Journal of College Science Teaching , ( 5 ), 46–52. [ Google Scholar ]
Greenhoot A. F., Semb G., Colombo J., Schreiber T. (2004). Prior beliefs and methodological concepts in scientific reasoning . Applied Cognitive Psychology , ( 2 ), 203–221. https://doi.org/10.1002/acp.959 . [ Google Scholar ]
Haaga D. A. F. (1993). Peer review of term papers in graduate psychology courses . Teaching of Psychology , ( 1 ), 28–32. https://doi.org/10.1207/s15328023top2001_5 . [ Google Scholar ]
Halonen J. S., Bosack T., Clay S., McCarthy M., Dunn D. S., Hill G. W., Whitlock K. (2003). A rubric for learning, teaching, and assessing scientific inquiry in psychology . Teaching of Psychology , ( 3 ), 196–208. https://doi.org/10.1207/S15328023TOP3003_01 . [ Google Scholar ]
Hand B., Keys C. W. (1999). Inquiry investigation . Science Teacher , ( 4 ), 27–29. [ Google Scholar ]
Holm S. (1979). A simple sequentially rejective multiple test procedure . Scandinavian Journal of Statistics , ( 2 ), 65–70. [ Google Scholar ]
Holyoak K. J., Morrison R. G. (2005). The Cambridge handbook of thinking and reasoning . New York: Cambridge University Press. [ Google Scholar ]
Insight Assessment. (2016a). California Critical Thinking Skills Test (CCTST) Retrieved September 26, 2017, from www.insightassessment.com/Products/Products-Summary/Critical-Thinking-Skills-Tests/California-Critical-Thinking-Skills-Test-CCTST .
Insight Assessment. (2016b). Sample thinking skills questions. Retrieved September 26, 2017, from www.insightassessment.com/Resources/Teaching-Training-and-Learning-Tools/node_1487 .
Kelly G. J., Takao A. (2002). Epistemic levels in argument: An analysis of university oceanography students’ use of evidence in writing . Science Education , ( 3 ), 314–342. https://doi.org/10.1002/sce.10024 . [ Google Scholar ]
Kuhn D., Dean D., Jr. (2004). Connecting scientific reasoning and causal inference . Journal of Cognition and Development , ( 2 ), 261–288. https://doi.org/10.1207/s15327647jcd0502_5 . [ Google Scholar ]
Kuhn D., Iordanou K., Pease M., Wirkala C. (2008). Beyond control of variables: What needs to develop to achieve skilled scientific thinking? . Cognitive Development , ( 4 ), 435–451. https://doi.org/10.1016/j.cogdev.2008.09.006 . [ Google Scholar ]
Lawson A. E. (2010). Basic inferences of scientific reasoning, argumentation, and discovery . Science Education , ( 2 ), 336–364. https://doi.org/10.1002/sce.20357 . [ Google Scholar ]
Meizlish D., LaVaque-Manty D., Silver N., Kaplan M. (2013). Think like/write like: Metacognitive strategies to foster students’ development as disciplinary thinkers and writers . In Thompson R. J. (Ed.), Changing the conversation about higher education (pp. 53–73). Lanham, MD: Rowman & Littlefield. [ Google Scholar ]
Miri B., David B.-C., Uri Z. (2007). Purposely teaching for the promotion of higher-order thinking skills: A case of critical thinking . Research in Science Education , ( 4 ), 353–369. https://doi.org/10.1007/s11165-006-9029-2 . [ Google Scholar ]
Moshman D. (2015). Epistemic cognition and development: The psychology of justification and truth . New York: Psychology Press. [ Google Scholar ]
National Research Council. (2000). How people learn: Brain, mind, experience, and school . Expanded ed. Washington, DC: National Academies Press. [ Google Scholar ]
Pukkila P. J. (2004). Introducing student inquiry in large introductory genetics classes . Genetics , ( 1 ), 11–18. https://doi.org/10.1534/genetics.166.1.11 . [ PMC free article ] [ PubMed ] [ Google Scholar ]
Quitadamo I. J., Faiola C. L., Johnson J. E., Kurtz M. J. (2008). Community-based inquiry improves critical thinking in general education biology . CBE—Life Sciences Education , ( 3 ), 327–337. https://doi.org/10.1187/cbe.07-11-0097 . [ PMC free article ] [ PubMed ] [ Google Scholar ]
Quitadamo I. J., Kurtz M. J. (2007). Learning to improve: Using writing to increase critical thinking performance in general education biology . CBE—Life Sciences Education , ( 2 ), 140–154. https://doi.org/10.1187/cbe.06-11-0203 . [ PMC free article ] [ PubMed ] [ Google Scholar ]
Reynolds J. A., Smith R., Moskovitz C., Sayle A. (2009). BioTAP: A systematic approach to teaching scientific writing and evaluating undergraduate theses . BioScience , ( 10 ), 896–903. https://doi.org/10.1525/bio.2009.59.10.11 . [ Google Scholar ]
Reynolds J. A., Thaiss C., Katkin W., Thompson R. J. (2012). Writing-to-learn in undergraduate science education: A community-based, conceptually driven approach . CBE—Life Sciences Education , ( 1 ), 17–25. https://doi.org/10.1187/cbe.11-08-0064 . [ PMC free article ] [ PubMed ] [ Google Scholar ]
Reynolds J. A., Thompson R. J. (2011). Want to improve undergraduate thesis writing? Engage students and their faculty readers in scientific peer review . CBE—Life Sciences Education , ( 2 ), 209–215. https://doi.org/10.1187/cbe.10-10-0127 . [ PMC free article ] [ PubMed ] [ Google Scholar ]
Rhemtulla M., Brosseau-Liard P. E., Savalei V. (2012). When can categorical variables be treated as continuous? A comparison of robust continuous and categorical SEM estimation methods under suboptimal conditions . Psychological Methods , ( 3 ), 354–373. https://doi.org/10.1037/a0029315 . [ PubMed ] [ Google Scholar ]
Stephenson N. S., Sadler-McKnight N. P. (2016). Developing critical thinking skills using the science writing heuristic in the chemistry laboratory . Chemistry Education Research and Practice , ( 1 ), 72–79. https://doi.org/10.1039/C5RP00102A . [ Google Scholar ]
Tariq V. N., Stefani L. A. J., Butcher A. C., Heylings D. J. A. (1998). Developing a new approach to the assessment of project work . Assessment and Evaluation in Higher Education , ( 3 ), 221–240. https://doi.org/10.1080/0260293980230301 . [ Google Scholar ]
Timmerman B. E. C., Strickland D. C., Johnson R. L., Payne J. R. (2011). Development of a “universal” rubric for assessing undergraduates’ scientific reasoning skills using scientific writing . Assessment and Evaluation in Higher Education , ( 5 ), 509–547. https://doi.org/10.1080/02602930903540991 . [ Google Scholar ]
Topping K. J., Smith E. F., Swanson I., Elliot A. (2000). Formative peer assessment of academic writing between postgraduate students . Assessment and Evaluation in Higher Education , ( 2 ), 149–169. https://doi.org/10.1080/713611428 . [ Google Scholar ]
Willison J., O’Regan K. (2007). Commonly known, commonly not known, totally unknown: A framework for students becoming researchers . Higher Education Research and Development , ( 4 ), 393–409. https://doi.org/10.1080/07294360701658609 . [ Google Scholar ]
Woodin T., Carter V. C., Fletcher L. (2010). Vision and Change in Biology Undergraduate Education: A Call for Action—Initial responses . CBE—Life Sciences Education , ( 2 ), 71–73. https://doi.org/10.1187/cbe.10-03-0044 . [ PMC free article ] [ PubMed ] [ Google Scholar ]
Zeineddin A., Abd-El-Khalick F. (2010). Scientific reasoning and epistemological commitments: Coordination of theory and evidence among college science students . Journal of Research in Science Teaching , ( 9 ), 1064–1093. https://doi.org/10.1002/tea.20368 . [ Google Scholar ]
Zimmerman C. (2000). The development of scientific reasoning skills . Developmental Review , ( 1 ), 99–149. https://doi.org/10.1006/drev.1999.0497 . [ Google Scholar ]
Zimmerman C. (2007). The development of scientific thinking skills in elementary and middle school . Developmental Review , ( 2 ), 172–223. https://doi.org/10.1016/j.dr.2006.12.001 . [ Google Scholar ]

Tips for Online Students , Tips for Students

Why Is Critical Thinking Important? A Survival Guide

Updated: December 7, 2023

Published: April 2, 2020

Why-Is-Critical-Thinking-Important-a-Survival-Guide

Why is critical thinking important? The decisions that you make affect your quality of life. And if you want to ensure that you live your best, most successful and happy life, you’re going to want to make conscious choices. That can be done with a simple thing known as critical thinking. Here’s how to improve your critical thinking skills and make decisions that you won’t regret.

What Is Critical Thinking?

You’ve surely heard of critical thinking, but you might not be entirely sure what it really means, and that’s because there are many definitions. For the most part, however, we think of critical thinking as the process of analyzing facts in order to form a judgment. Basically, it’s thinking about thinking.

How Has The Definition Evolved Over Time?

The first time critical thinking was documented is believed to be in the teachings of Socrates , recorded by Plato. But throughout history, the definition has changed.

Today it is best understood by philosophers and psychologists and it’s believed to be a highly complex concept. Some insightful modern-day critical thinking definitions include :

“Reasonable, reflective thinking that is focused on deciding what to believe or do.”
“Deciding what’s true and what you should do.”

The Importance Of Critical Thinking

Why is critical thinking important? Good question! Here are a few undeniable reasons why it’s crucial to have these skills.

1. Critical Thinking Is Universal

Critical thinking is a domain-general thinking skill. What does this mean? It means that no matter what path or profession you pursue, these skills will always be relevant and will always be beneficial to your success. They are not specific to any field.

2. Crucial For The Economy

Our future depends on technology, information, and innovation. Critical thinking is needed for our fast-growing economies, to solve problems as quickly and as effectively as possible.

3. Improves Language & Presentation Skills

In order to best express ourselves, we need to know how to think clearly and systematically — meaning practice critical thinking! Critical thinking also means knowing how to break down texts, and in turn, improve our ability to comprehend.

4. Promotes Creativity

By practicing critical thinking, we are allowing ourselves not only to solve problems but also to come up with new and creative ideas to do so. Critical thinking allows us to analyze these ideas and adjust them accordingly.

5. Important For Self-Reflection

Without critical thinking, how can we really live a meaningful life? We need this skill to self-reflect and justify our ways of life and opinions. Critical thinking provides us with the tools to evaluate ourselves in the way that we need to.

Woman deep into thought as she looks out the window, using her critical thinking skills to do some self-reflection.

6. The Basis Of Science & Democracy

In order to have a democracy and to prove scientific facts, we need critical thinking in the world. Theories must be backed up with knowledge. In order for a society to effectively function, its citizens need to establish opinions about what’s right and wrong (by using critical thinking!).

Benefits Of Critical Thinking

We know that critical thinking is good for society as a whole, but what are some benefits of critical thinking on an individual level? Why is critical thinking important for us?

1. Key For Career Success

Critical thinking is crucial for many career paths. Not just for scientists, but lawyers , doctors, reporters, engineers , accountants, and analysts (among many others) all have to use critical thinking in their positions. In fact, according to the World Economic Forum, critical thinking is one of the most desirable skills to have in the workforce, as it helps analyze information, think outside the box, solve problems with innovative solutions, and plan systematically.

2. Better Decision Making

There’s no doubt about it — critical thinkers make the best choices. Critical thinking helps us deal with everyday problems as they come our way, and very often this thought process is even done subconsciously. It helps us think independently and trust our gut feeling.

3. Can Make You Happier!

While this often goes unnoticed, being in touch with yourself and having a deep understanding of why you think the way you think can really make you happier. Critical thinking can help you better understand yourself, and in turn, help you avoid any kind of negative or limiting beliefs, and focus more on your strengths. Being able to share your thoughts can increase your quality of life.

4. Form Well-Informed Opinions

There is no shortage of information coming at us from all angles. And that’s exactly why we need to use our critical thinking skills and decide for ourselves what to believe. Critical thinking allows us to ensure that our opinions are based on the facts, and help us sort through all that extra noise.

5. Better Citizens

One of the most inspiring critical thinking quotes is by former US president Thomas Jefferson: “An educated citizenry is a vital requisite for our survival as a free people.” What Jefferson is stressing to us here is that critical thinkers make better citizens, as they are able to see the entire picture without getting sucked into biases and propaganda.

6. Improves Relationships

While you may be convinced that being a critical thinker is bound to cause you problems in relationships, this really couldn’t be less true! Being a critical thinker can allow you to better understand the perspective of others, and can help you become more open-minded towards different views.

7. Promotes Curiosity

Critical thinkers are constantly curious about all kinds of things in life, and tend to have a wide range of interests. Critical thinking means constantly asking questions and wanting to know more, about why, what, who, where, when, and everything else that can help them make sense of a situation or concept, never taking anything at face value.

8. Allows For Creativity

Critical thinkers are also highly creative thinkers, and see themselves as limitless when it comes to possibilities. They are constantly looking to take things further, which is crucial in the workforce.

9. Enhances Problem Solving Skills

Those with critical thinking skills tend to solve problems as part of their natural instinct. Critical thinkers are patient and committed to solving the problem, similar to Albert Einstein, one of the best critical thinking examples, who said “It’s not that I’m so smart; it’s just that I stay with problems longer.” Critical thinkers’ enhanced problem-solving skills makes them better at their jobs and better at solving the world’s biggest problems. Like Einstein, they have the potential to literally change the world.

10. An Activity For The Mind

Just like our muscles, in order for them to be strong, our mind also needs to be exercised and challenged. It’s safe to say that critical thinking is almost like an activity for the mind — and it needs to be practiced. Critical thinking encourages the development of many crucial skills such as logical thinking, decision making, and open-mindness.

11. Creates Independence

When we think critically, we think on our own as we trust ourselves more. Critical thinking is key to creating independence, and encouraging students to make their own decisions and form their own opinions.

12. Crucial Life Skill

Critical thinking is crucial not just for learning, but for life overall! Education isn’t just a way to prepare ourselves for life, but it’s pretty much life itself. Learning is a lifelong process that we go through each and every day.

How to Think Critically

Now that you know the benefits of thinking critically, how do you actually do it?

How To Improve Your Critical Thinking

Define Your Question: When it comes to critical thinking, it’s important to always keep your goal in mind. Know what you’re trying to achieve, and then figure out how to best get there.
Gather Reliable Information: Make sure that you’re using sources you can trust — biases aside. That’s how a real critical thinker operates!
Ask The Right Questions: We all know the importance of questions, but be sure that you’re asking the right questions that are going to get you to your answer.
Look Short & Long Term: When coming up with solutions, think about both the short- and long-term consequences. Both of them are significant in the equation.
Explore All Sides: There is never just one simple answer, and nothing is black or white. Explore all options and think outside of the box before you come to any conclusions.

How Is Critical Thinking Developed At School?

Critical thinking is developed in nearly everything we do. However, much of this important skill is encouraged to be practiced at school, and rightfully so! Critical thinking goes beyond just thinking clearly — it’s also about thinking for yourself.

When a teacher asks a question in class, students are given the chance to answer for themselves and think critically about what they learned and what they believe to be accurate. When students work in groups and are forced to engage in discussion, this is also a great chance to expand their thinking and use their critical thinking skills.

How Does Critical Thinking Apply To Your Career?

Once you’ve finished school and entered the workforce, your critical thinking journey only expands and grows from here!

Impress Your Employer

Employers value employees who are critical thinkers, ask questions, offer creative ideas, and are always ready to offer innovation against the competition. No matter what your position or role in a company may be, critical thinking will always give you the power to stand out and make a difference.

Careers That Require Critical Thinking

Some of many examples of careers that require critical thinking include:

Human resources specialist
Marketing associate
Business analyst

Truth be told however, it’s probably harder to come up with a professional field that doesn’t require any critical thinking!

Photo by Oladimeji Ajegbile from Pexels

What is someone with critical thinking skills capable of doing.

Someone with critical thinking skills is able to think rationally and clearly about what they should or not believe. They are capable of engaging in their own thoughts, and doing some reflection in order to come to a well-informed conclusion.

A critical thinker understands the connections between ideas, and is able to construct arguments based on facts, as well as find mistakes in reasoning.

The Process Of Critical Thinking

The process of critical thinking is highly systematic.

What Are Your Goals?

Critical thinking starts by defining your goals, and knowing what you are ultimately trying to achieve.

Once you know what you are trying to conclude, you can foresee your solution to the problem and play it out in your head from all perspectives.

What Does The Future Of Critical Thinking Hold?

The future of critical thinking is the equivalent of the future of jobs. In 2020, critical thinking was ranked as the 2nd top skill (following complex problem solving) by the World Economic Forum .

We are dealing with constant unprecedented changes, and what success is today, might not be considered success tomorrow — making critical thinking a key skill for the future workforce.

Why Is Critical Thinking So Important?

Why is critical thinking important? Critical thinking is more than just important! It’s one of the most crucial cognitive skills one can develop.

By practicing well-thought-out thinking, both your thoughts and decisions can make a positive change in your life, on both a professional and personal level. You can hugely improve your life by working on your critical thinking skills as often as you can.

Thinking critically on critical thinking: why scientists’ skills need to spread

why is critical thinking important to psychological science

Lecturer in Psychology, University of Tasmania

Disclosure statement

Rachel Grieve does not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.

University of Tasmania provides funding as a member of The Conversation AU.

View all partners

MATHS AND SCIENCE EDUCATION: We’ve asked our authors about the state of maths and science education in Australia and its future direction. Today, Rachel Grieve discusses why we need to spread science-specific skills into the wider curriculum.

When we think of science and maths, stereotypical visions of lab coats, test-tubes, and formulae often spring to mind.

But more important than these stereotypes are the methods that underpin the work scientists do – namely generating and systematically testing hypotheses. A key part of this is critical thinking.

It’s a skill that often feels in short supply these days, but you don’t necessarily need to study science or maths in order gain it. It’s time to take critical thinking out of the realm of maths and science and broaden it into students’ general education.

What is critical thinking?

Critical thinking is a reflective and analytical style of thinking, with its basis in logic, rationality, and synthesis. It means delving deeper and asking questions like: why is that so? Where is the evidence? How good is that evidence? Is this a good argument? Is it biased? Is it verifiable? What are the alternative explanations?

Critical thinking moves us beyond mere description and into the realms of scientific inference and reasoning. This is what enables discoveries to be made and innovations to be fostered.

For many scientists, critical thinking becomes (seemingly) intuitive, but like any skill set, critical thinking needs to be taught and cultivated. Unfortunately, educators are unable to deposit this information directly into their students’ heads. While the theory of critical thinking can be taught, critical thinking itself needs to be experienced first-hand.

So what does this mean for educators trying to incorporate critical thinking within their curricula? We can teach students the theoretical elements of critical thinking. Take for example working through [statistical problems](http://wdeneys.org/data/COGNIT_1695.pdf](http://wdeneys.org/data/COGNIT_1695.pdf) like this one:

In a 1,000-person study, four people said their favourite series was Star Trek and 996 said Days of Our Lives. Jeremy is a randomly chosen participant in this study, is 26, and is doing graduate studies in physics. He stays at home most of the time and likes to play videogames. What is most likely? a. Jeremy’s favourite series is Star Trek b. Jeremy’s favourite series is Days of Our Lives

Some critical thought applied to this problem allows us to know that Jeremy is most likely to prefer Days of Our Lives.

Can you teach it?

It’s well established that statistical training is associated with improved decision-making. But the idea of “teaching” critical thinking is itself an oxymoron: critical thinking can really only be learned through practice. Thus, it is not surprising that student engagement with the critical thinking process itself is what pays the dividends for students.

As such, educators try to connect students with the subject matter outside the lecture theatre or classroom. For example, problem based learning is now widely used in the health sciences, whereby students must figure out the key issues related to a case and direct their own learning to solve that problem. Problem based learning has clear parallels with real life practice for health professionals.

Critical thinking goes beyond what might be on the final exam and life-long learning becomes the key. This is a good thing, as practice helps to improve our ability to think critically over time .

Just for scientists?

For those engaging with science, learning the skills needed to be a critical consumer of information is invaluable. But should these skills remain in the domain of scientists? Clearly not: for those engaging with life, being a critical consumer of information is also invaluable, allowing informed judgement.

Being able to actively consider and evaluate information, identify biases, examine the logic of arguments, and tolerate ambiguity until the evidence is in would allow many people from all backgrounds to make better decisions. While these decisions can be trivial (does that miracle anti-wrinkle cream really do what it claims?), in many cases, reasoning and decision-making can have a substantial impact, with some decisions have life-altering effects. A timely case-in-point is immunisation.

Pushing critical thinking from the realms of science and maths into the broader curriculum may lead to far-reaching outcomes. With increasing access to information on the internet, giving individuals the skills to critically think about that information may have widespread benefit, both personally and socially.

The value of science education might not always be in the facts, but in the thinking.

This is the sixth part of our series Maths and Science Education .

Maths and science education

Data Manager

Research Support Officer

Director, Social Policy

Head, School of Psychology

Senior Research Fellow - Women's Health Services

Bipolar Disorder
Therapy Center
When To See a Therapist
Types of Therapy
Best Online Therapy
Best Couples Therapy
Best Family Therapy
Managing Stress
Sleep and Dreaming
Understanding Emotions
Self-Improvement
Healthy Relationships
Student Resources
Personality Types
Guided Meditations
Verywell Mind Insights
2024 Verywell Mind 25
Mental Health in the Classroom
Editorial Process
Meet Our Review Board
Crisis Support

What Is Cognitive Psychology?

The Science of How We Think

Kendra Cherry, MS, is a psychosocial rehabilitation specialist, psychology educator, and author of the "Everything Psychology Book."

Steven Gans, MD is board-certified in psychiatry and is an active supervisor, teacher, and mentor at Massachusetts General Hospital.

Topics in Cognitive Psychology

Current Research
Cognitive Approach in Practice

Careers in Cognitive Psychology

How cognitive psychology differs from other branches of psychology, frequently asked questions.

Cognitive psychology involves the study of internal mental processes—all of the workings inside your brain, including perception, thinking, memory, attention, language, problem-solving, and learning.

Cognitive psychology--the study of how people think and process information--helps researchers understand the human brain. It also allows psychologists to help people deal with psychological difficulties.

This article discusses what cognitive psychology is, the history of this field, and current directions for research. It also covers some of the practical applications for cognitive psychology research and related career options you might consider.

Findings from cognitive psychology help us understand how people think, including how they acquire and store memories. By knowing more about how these processes work, psychologists can develop new ways of helping people with cognitive problems.

Cognitive psychologists explore a wide variety of topics related to thinking processes. Some of these include:

Attention --our ability to process information in the environment while tuning out irrelevant details
Choice-based behavior --actions driven by a choice among other possibilities
Decision-making
Information processing
Language acquisition --how we learn to read, write, and express ourselves
Problem-solving
Speech perception -how we process what others are saying
Visual perception --how we see the physical world around us

History of Cognitive Psychology

Although it is a relatively young branch of psychology , it has quickly grown to become one of the most popular subfields. Cognitive psychology grew into prominence between the 1950s and 1970s.

Prior to this time, behaviorism was the dominant perspective in psychology. This theory holds that we learn all our behaviors from interacting with our environment. It focuses strictly on observable behavior, not thought and emotion. Then, researchers became more interested in the internal processes that affect behavior instead of just the behavior itself.

This shift is often referred to as the cognitive revolution in psychology. During this time, a great deal of research on topics including memory, attention, and language acquisition began to emerge.

In 1967, the psychologist Ulric Neisser introduced the term cognitive psychology, which he defined as the study of the processes behind the perception, transformation, storage, and recovery of information.

Cognitive psychology became more prominent after the 1950s as a result of the cognitive revolution.

Current Research in Cognitive Psychology

The field of cognitive psychology is both broad and diverse. It touches on many aspects of daily life. There are numerous practical applications for this research, such as providing help coping with memory disorders, making better decisions , recovering from brain injury, treating learning disorders, and structuring educational curricula to enhance learning.

Current research on cognitive psychology helps play a role in how professionals approach the treatment of mental illness, traumatic brain injury, and degenerative brain diseases.

Thanks to the work of cognitive psychologists, we can better pinpoint ways to measure human intellectual abilities, develop new strategies to combat memory problems, and decode the workings of the human brain—all of which ultimately have a powerful impact on how we treat cognitive disorders.

The field of cognitive psychology is a rapidly growing area that continues to add to our understanding of the many influences that mental processes have on our health and daily lives.

From understanding how cognitive processes change as a child develops to looking at how the brain transforms sensory inputs into perceptions, cognitive psychology has helped us gain a deeper and richer understanding of the many mental events that contribute to our daily existence and overall well-being.

The Cognitive Approach in Practice

In addition to adding to our understanding of how the human mind works, the field of cognitive psychology has also had an impact on approaches to mental health. Before the 1970s, many mental health treatments were focused more on psychoanalytic , behavioral , and humanistic approaches.

The so-called "cognitive revolution" put a greater emphasis on understanding the way people process information and how thinking patterns might contribute to psychological distress. Thanks to research in this area, new approaches to treatment were developed to help treat depression, anxiety, phobias, and other psychological disorders .

Cognitive behavioral therapy and rational emotive behavior therapy are two methods in which clients and therapists focus on the underlying cognitions, or thoughts, that contribute to psychological distress.

What Is Cognitive Behavioral Therapy?

Cognitive behavioral therapy (CBT) is an approach that helps clients identify irrational beliefs and other cognitive distortions that are in conflict with reality and then aid them in replacing such thoughts with more realistic, healthy beliefs.

If you are experiencing symptoms of a psychological disorder that would benefit from the use of cognitive approaches, you might see a psychologist who has specific training in these cognitive treatment methods.

These professionals frequently go by titles other than cognitive psychologists, such as psychiatrists, clinical psychologists , or counseling psychologists , but many of the strategies they use are rooted in the cognitive tradition.

Many cognitive psychologists specialize in research with universities or government agencies. Others take a clinical focus and work directly with people who are experiencing challenges related to mental processes. They work in hospitals, mental health clinics, and private practices.

Research psychologists in this area often concentrate on a particular topic, such as memory. Others work directly on health concerns related to cognition, such as degenerative brain disorders and brain injuries.

Treatments rooted in cognitive research focus on helping people replace negative thought patterns with more positive, realistic ones. With the help of cognitive psychologists, people are often able to find ways to cope and even overcome such difficulties.

Reasons to Consult a Cognitive Psychologist

Alzheimer's disease, dementia, or memory loss
Brain trauma treatment
Cognitive therapy for a mental health condition
Interventions for learning disabilities
Perceptual or sensory issues
Therapy for a speech or language disorder

Whereas behavioral and some other realms of psychology focus on actions--which are external and observable--cognitive psychology is instead concerned with the thought processes behind the behavior. Cognitive psychologists see the mind as if it were a computer, taking in and processing information, and seek to understand the various factors involved.

A Word From Verywell

Cognitive psychology plays an important role in understanding the processes of memory, attention, and learning. It can also provide insights into cognitive conditions that may affect how people function.

Being diagnosed with a brain or cognitive health problem can be daunting, but it is important to remember that you are not alone. Together with a healthcare provider, you can come up with an effective treatment plan to help address brain health and cognitive problems.

Your treatment may involve consulting with a cognitive psychologist who has a background in the specific area of concern that you are facing, or you may be referred to another mental health professional that has training and experience with your particular condition.

Ulric Neisser is considered the founder of cognitive psychology. He was the first to introduce the term and to define the field of cognitive psychology. His primary interests were in the areas of perception and memory, but he suggested that all aspects of human thought and behavior were relevant to the study of cognition.

A cognitive map refers to a mental representation of an environment. Such maps can be formed through observation as well as through trial and error. These cognitive maps allow people to orient themselves in their environment.

While they share some similarities, there are some important differences between cognitive neuroscience and cognitive psychology. While cognitive psychology focuses on thinking processes, cognitive neuroscience is focused on finding connections between thinking and specific brain activity. Cognitive neuroscience also looks at the underlying biology that influences how information is processed.

Cognitive psychology is a form of experimental psychology. Cognitive psychologists use experimental methods to study the internal mental processes that play a role in behavior.

Sternberg RJ, Sternberg K. Cognitive Psychology . Wadsworth/Cengage Learning.

Krapfl JE. Behaviorism and society . Behav Anal. 2016;39(1):123-9. doi:10.1007/s40614-016-0063-8

Cutting JE. Ulric Neisser (1928-2012) . Am Psychol . 2012;67(6):492. doi:10.1037/a0029351

Ruggiero GM, Spada MM, Caselli G, Sassaroli S. A historical and theoretical review of cognitive behavioral therapies: from structural self-knowledge to functional processes . J Ration Emot Cogn Behav Ther . 2018;36(4):378-403. doi:10.1007/s10942-018-0292-8

Parvin P. Ulric Neisser, cognitive psychology pioneer, dies . Emory News Center.

APA Dictionary of Psychology. Cognitive map . American Psychological Association.

Forstmann BU, Wagenmakers EJ, Eichele T, Brown S, Serences JT. Reciprocal relations between cognitive neuroscience and formal cognitive models: opposites attract? . Trends Cogn Sci . 2011;15(6):272-279. doi:10.1016/j.tics.2011.04.002

By Kendra Cherry, MSEd Kendra Cherry, MS, is a psychosocial rehabilitation specialist, psychology educator, and author of the "Everything Psychology Book."

3. Critical Thinking in Science: How to Foster Scientific Reasoning Skills

Critical thinking in science is important largely because a lot of students have developed expectations about science that can prove to be counter-productive.

After various experiences — both in school and out — students often perceive science to be primarily about learning “authoritative” content knowledge: this is how the solar system works; that is how diffusion works; this is the right answer and that is not.

This perception allows little room for critical thinking in science, in spite of the fact that argument, reasoning, and critical thinking lie at the very core of scientific practice.

Argument, reasoning, and critical thinking lie at the very core of scientific practice.

In this article, we outline two of the best approaches to be most effective in fostering scientific reasoning. Both try to put students in a scientist’s frame of mind more than is typical in science education:

First, we look at small-group inquiry , where students formulate questions and investigate them in small groups. This approach is geared more toward younger students but has applications at higher levels too.
We also look science labs . Too often, science labs too often involve students simply following recipes or replicating standard results. Here, we offer tips to turn labs into spaces for independent inquiry and scientific reasoning.

I. Critical Thinking in Science and Scientific Inquiry

Even very young students can “think scientifically” under the right instructional support. A series of experiments , for instance, established that preschoolers can make statistically valid inferences about unknown variables. Through observation they are also capable of distinguishing actions that cause certain outcomes from actions that don’t. These innate capacities, however, have to be developed for students to grow up into rigorous scientific critical thinkers.

Even very young students can “think scientifically” under the right instructional support.

Although there are many techniques to get young children involved in scientific inquiry — encouraging them to ask and answer “why” questions, for instance — teachers can provide structured scientific inquiry experiences that are deeper than students can experience on their own.

Goals for Teaching Critical Thinking Through Scientific Inquiry

When it comes to teaching critical thinking via science, the learning goals may vary, but students should learn that:

Failure to agree is okay, as long as you have reasons for why you disagree about something.
The logic of scientific inquiry is iterative. Scientists always have to consider how they might improve your methods next time. This includes addressing sources of uncertainty.
Claims to knowledge usually require multiple lines of evidence and a “match” or “fit” between our explanations and the evidence we have.
Collaboration, argument, and discussion are central features of scientific reasoning.
Visualization, analysis, and presentation are central features of scientific reasoning.
Overarching concepts in scientific practice — such as uncertainty, measurement, and meaningful experimental contrasts — manifest themselves somewhat differently in different scientific domains.

How to Teaching Critical Thinking in Science Via Inquiry

Sometimes we think of science education as being either a “direct” approach, where we tell students about a concept, or an “inquiry-based” approach, where students explore a concept themselves.

But, especially, at the earliest grades, integrating both approaches can inform students of their options (i.e., generate and extend their ideas), while also letting students make decisions about what to do.

Like a lot of projects targeting critical thinking, limited classroom time is a challenge. Although the latest content standards, such as the Next Generation Science Standards , emphasize teaching scientific practices, many standardized tests still emphasize assessing scientific content knowledge.

The concept of uncertainty comes up in every scientific domain.

Creating a lesson that targets the right content is also an important aspect of developing authentic scientific experiences. It’s now more widely acknowledged that effective science instruction involves the interaction between domain-specific knowledge and domain-general knowledge, and that linking an inquiry experience to appropriate target content is vital.

For instance, the concept of uncertainty comes up in every scientific domain. But the sources of uncertainty coming from any given measurement vary tremendously by discipline. It requires content knowledge to know how to wisely apply the concept of uncertainty.

Tips and Challenges for teaching critical thinking in science

Teachers need to grapple with student misconceptions. Student intuition about how the world works — the way living things grow and behave, the way that objects fall and interact — often conflicts with scientific explanations. As part of the inquiry experience, teachers can help students to articulate these intuitions and revise them through argument and evidence.

Group composition is another challenge. Teachers will want to avoid situations where one member of the group will simply “take charge” of the decision-making, while other member(s) disengage. In some cases, grouping students by current ability level can make the group work more productive.

Another approach is to establish group norms that help prevent unproductive group interactions. A third tactic is to have each group member learn an essential piece of the puzzle prior to the group work, so that each member is bringing something valuable to the table (which other group members don’t yet know).

It’s critical to ask students about how certain they are in their observations and explanations and what they could do better next time. When disagreements arise about what to do next or how to interpret evidence, the instructor should model good scientific practice by, for instance, getting students to think about what kind of evidence would help resolve the disagreement or whether there’s a compromise that might satisfy both groups.

The subjects of the inquiry experience and the tools at students’ disposal will depend upon the class and the grade level. Older students may be asked to create mathematical models, more sophisticated visualizations, and give fuller presentations of their results.

Lesson Plan Outline

This lesson plan takes a small-group inquiry approach to critical thinking in science. It asks students to collaboratively explore a scientific question, or perhaps a series of related questions, within a scientific domain.

Suppose students are exploring insect behavior. Groups may decide what questions to ask about insect behavior; how to observe, define, and record insect behavior; how to design an experiment that generates evidence related to their research questions; and how to interpret and present their results.

An in-depth inquiry experience usually takes place over the course of several classroom sessions, and includes classroom-wide instruction, small-group work, and potentially some individual work as well.

Students, especially younger students, will typically need some background knowledge that can inform more independent decision-making. So providing classroom-wide instruction and discussion before individual group work is a good idea.

For instance, Kathleen Metz had students observe insect behavior, explore the anatomy of insects, draw habitat maps, and collaboratively formulate (and categorize) research questions before students began to work more independently.

The subjects of a science inquiry experience can vary tremendously: local weather patterns, plant growth, pollution, bridge-building. The point is to engage students in multiple aspects of scientific practice: observing, formulating research questions, making predictions, gathering data, analyzing and interpreting data, refining and iterating the process.

As student groups take responsibility for their own investigation, teachers act as facilitators. They can circulate around the room, providing advice and guidance to individual groups. If classroom-wide misconceptions arise, they can pause group work to address those misconceptions directly and re-orient the class toward a more productive way of thinking.

Throughout the process, teachers can also ask questions like:

What are your assumptions about what’s going on? How can you check your assumptions?
Suppose that your results show X, what would you conclude?
If you had to do the process over again, what would you change? Why?

II. Rethinking Science Labs

Beyond changing how students approach scientific inquiry, we also need to rethink science labs. After all, science lab activities are ubiquitous in science classrooms and they are a great opportunity to teach critical thinking skills.

Often, however, science labs are merely recipes that students follow to verify standard values (such as the force of acceleration due to gravity) or relationships between variables (such as the relationship between force, mass, and acceleration) known to the students beforehand.

This approach does not usually involve critical thinking: students are not making many decisions during the process, and they do not reflect on what they’ve done except to see whether their experimental data matches the expected values.

With some small tweaks, however, science labs can involve more critical thinking. Science lab activities that give students not only the opportunity to design, analyze, and interpret the experiment, but re -design, re -analyze, and re -interpret the experiment provides ample opportunity for grappling with evidence and evidence-model relationships, particularly if students don’t know what answer they should be expecting beforehand.

Such activities improve scientific reasoning skills, such as:

Evaluating quantitative data
Plausible scientific explanations for observed patterns

And also broader critical thinking skills, like:

Comparing models to data, and comparing models to each other
Thinking about what kind of evidence supports one model or another
Being open to changing your beliefs based on evidence

Traditional science lab experiences bear little resemblance to actual scientific practice. Actual practice involves decision-making under uncertainty, trial-and-error, tweaking experimental methods over time, testing instruments, and resolving conflicts among different kinds of evidence. Traditional in-school science labs rarely involve these things.

Traditional science lab experiences bear little resemblance to actual scientific practice.

When teachers use science labs as opportunities to engage students in the kinds of dilemmas that scientists actually face during research, students make more decisions and exhibit more sophisticated reasoning.

In the lesson plan below, students are asked to evaluate two models of drag forces on a falling object. One model assumes that drag increases linearly with the velocity of the falling object. Another model assumes that drag increases quadratically (e.g., with the square of the velocity). Students use a motion detector and computer software to create a plot of the position of a disposable paper coffee filter as it falls to the ground. Among other variables, students can vary the number of coffee filters they drop at once, the height at which they drop them, how they drop them, and how they clean their data. This is an approach to scaffolding critical thinking: a way to get students to ask the right kinds of questions and think in the way that scientists tend to think.

Design an experiment to test which model best characterizes the motion of the coffee filters.

Things to think about in your design:

What are the relevant variables to control and which ones do you need to explore?
What are some logistical issues associated with the data collection that may cause unnecessary variability (either random or systematic) or mistakes?
How can you control or measure these?
What ways can you graph your data and which ones will help you figure out which model better describes your data?

Discuss your design with other groups and modify as you see fit.

Initial data collection

Conduct a quick trial-run of your experiment so that you can evaluate your methods.

Do your graphs provide evidence of which model is the best?
What ways can you improve your methods, data, or graphs to make your case more convincing?
Do you need to change how you’re collecting data?
Do you need to take data at different regions?
Do you just need more data?
Do you need to reduce your uncertainty?

After this initial evaluation of your data and methods, conduct the desired improvements, changes, or additions and re-evaluate at the end.

In your lab notes, make sure to keep track of your progress and process as you go. As always, your final product is less important than how you get there.

How to Make Science Labs Run Smoothly

Managing student expectations . As with many other lesson plans that incorporate critical thinking, students are not used to having so much freedom. As with the example lesson plan above, it’s important to scaffold student decision-making by pointing out what decisions have to be made, especially as students are transitioning to this approach.

Supporting student reasoning . Another challenge is to provide guidance to student groups without telling them how to do something. Too much “telling” diminishes student decision-making, but not enough support may leave students simply not knowing what to do.

There are several key strategies teachers can try out here:

Point out an issue with their data collection process without specifying exactly how to solve it.
Ask a lab group how they would improve their approach.
Ask two groups with conflicting results to compare their results, methods, and analyses.

Download our Teachers’ Guide

(please click here)

Sources and Resources

Lehrer, R., & Schauble, L. (2007). Scientific thinking and scientific literacy . Handbook of child psychology , Vol. 4. Wiley. A review of research on scientific thinking and experiments on teaching scientific thinking in the classroom.

Metz, K. (2004). Children’s understanding of scientific inquiry: Their conceptualizations of uncertainty in investigations of their own design . Cognition and Instruction 22(2). An example of a scientific inquiry experience for elementary school students.

The Next Generation Science Standards . The latest U.S. science content standards.

Concepts of Evidence A collection of important concepts related to evidence that cut across scientific disciplines.

Scienceblind A book about children’s science misconceptions and how to correct them.

Holmes, N. G., Keep, B., & Wieman, C. E. (2020). Developing scientific decision making by structuring and supporting student agency. Physical Review Physics Education Research , 16 (1), 010109. A research study on minimally altering traditional lab approaches to incorporate more critical thinking. The drag example was taken from this piece.

ISLE , led by E. Etkina. A platform that helps teachers incorporate more critical thinking in physics labs.

Holmes, N. G., Wieman, C. E., & Bonn, D. A. (2015). Teaching critical thinking . Proceedings of the National Academy of Sciences , 112 (36), 11199-11204. An approach to improving critical thinking and reflection in science labs. Walker, J. P., Sampson, V., Grooms, J., Anderson, B., & Zimmerman, C. O. (2012). Argument-driven inquiry in undergraduate chemistry labs: The impact on students’ conceptual understanding, argument skills, and attitudes toward science . Journal of College Science Teaching , 41 (4), 74-81. A large-scale research study on transforming chemistry labs to be more inquiry-based.

Privacy Overview

Teaching: On the Benefits of Critical Ignoring

Current Directions in Psychological Science
Social Media
Teaching Current Directions

Aimed at integrating cutting-edge psychological science into the classroom, Teaching Current Directions in Psychological Science offers advice and how-to guidance about teaching a particular area of research or topic in psychological science that has been the focus of an article in the APS journal Current Directions in Psychological Science .

Also see Teaching: The Unexpected Pleasure of Doing Good .

Kozyreva, A., Wineburg, S., Lewandowsky, S., & Hertwig, R. (2022). Critical Ignoring as a Core Competence for Digital Citizens. Current Directions in Psychological Science , 0 (0).

People study psychology to understand themselves, others, and their global community. To foster such understanding, psychological scientists teach critical thinking. Using the scientific method, students learn how to approach competing ideas with an analytical mindset—leading them to rely on evidence rather than anecdote or intuition.

According to Anastasia Kozyreva, Sam Wineburg, and APS Fellows Stephan Lewandowsky and Ralph Hertwig (2022), psychological scientists should also teach critical ignoring , defined as “choosing what to ignore and where to invest one’s limited attentional capacities.” The proliferation of digital information has given people greater access to information. Yet there are few checks and balances to separate false and misleading information from the truth. Thus, people must become smart ignorers of information (Hertwig & Engel, 2016).

To engage in critical ignoring, Kozyreva and colleagues encourage people to use three approaches:

Self-nudging: Redesign your environment to limit the temptation to consume unvetted information (Reijula & Hertwig, 2022). For example, people can use apps or web browser extensions that restrict their use of social media.
Lateral reading: Ignore people or organizations who refuse to let you cross-check their claims with independent verification from third parties, especially those that may be inclined to disagree with them. Start by verifying information from its original source. Next, seek out independent verification from other sources. Professional fact-checkers commonly use lateral reading (Wineburg & McGrew, 2019). Don’t invest your limited attentional resources listening to people or organizations that refuse to have their claims verified.
“Do Not Feed the Trolls”: Avoid trolls—people who seek to deceive or harm others online. Trolls score highly on sadism (example item: “I enjoy hurting people”), psychopathy (“Payback needs to be quick and nasty”), and Machiavellianism (“It’s not wise to tell your secrets”). Trolls also find annoying and upsetting others reinforcing (Craker & March, 2016). Any time you catch a whiff of someone engaging in troll-like behavior, block or ignore them.

Ask students to select two topics from the following list that they feel comfortable thinking about:

Student debt crisis
Cancel culture
Critical race theory
Gun control
Mandatory Covid-19 vaccines
Abortion
White supremacy
Animal rights
Climate change
Immigration reform

Tell students about the importance of critical ignoring, which means ignoring some information and investing their limited attentional resources elsewhere. Next, ask students to consider how they can use the three essential strategies of ignoring to understand better the topics they chose:

Self-nudging: How can students redesign their environment to limit the temptation to consume unvetted information related to their chosen topics? How could they limit the time they spend on certain websites? Should they avoid some websites? Why? What other actions can they take to make these environmental changes?
Lateral reading: Ask students to cross-check information from a source (author, organization) and determine whether it conforms to information elsewhere (e.g., Wikipedia, Our World in Data). Students can start by verifying information from its source and then seek independent verification from other sources. Encourage students to try to verify information from independent sources that are either neutral or opposed to a particular position. How does lateral reading help students pay attention to the most relevant information? How might their learning experience differ if they decided to ignore people or organizations that refused to have their claims confirmed by independent sources?
“Do Not Feed the Trolls”: How might students avoid online trolls related to their topics? Have they blocked or ignored trolls in the past? Why might ignoring trolls be the safest and most effective strategy?

Psychological scientists need to teach both critical thinking and critical ignoring. Faced with a deluge of digital information, people need guidance on deciding what information to ignore and where to invest their limited attentional resources. By self-nudging, lateral reading, and starving online trolls, people can better understand themselves, their fellows, and their global community.

Feedback on this article? Email [email protected] or login to comment. Interested in writing for us? Read our contributor guidelines .

References

Craker, N., & March, E. (2016). The dark side of Facebook®: The Dark Tetrad, negative social potency, and trolling behaviors. Personality and Individual Differences , 102 , 79–84. https://doi.org/10.1016/j.paid.2016.06.043

Hertwig, R., & Engel, C. (2016). Homo ignorans: Deliberately choosing not to know. Perspectives on Psychological Science , 11 (3), 359–372. https://doi.org/10.1177/1745691616635594

Reijula, S., & Hertwig, R. (2022). Self-nudging and the citizen choice architect. Behavioural Public Policy , 6 (1), 119–149. https://doi.org/10.1017/bpp.2020.5

Wineburg, S., & McGrew, S. (2019). Lateral reading and the nature of expertise: Reading less and learning more when evaluating digital information. Teachers College Record , 121 (11), 1–40. https://www.tcrecord.org/Content.asp?ContentId=22806

APS regularly opens certain online articles for discussion on our website. Effective February 2021, you must be a logged-in APS member to post comments. By posting a comment, you agree to our Community Guidelines and the display of your profile information, including your name and affiliation. Any opinions, findings, conclusions, or recommendations present in article comments are those of the writers and do not necessarily reflect the views of APS or the article’s author. For more information, please see our Community Guidelines .

Please login with your APS account to comment.

About the Authors

APS Fellow C. Nathan DeWall is a professor of psychology at the University of Kentucky. His research interests include social acceptance and rejection, self-control, and aggression. DeWall can be contacted at [email protected] .

Empirical Evidence Is My Love Language

Teaching: The idea of love languages has become hugely popular and the term itself is pervasive in popular culture. This article provides teaching materials to encourage students to think critically about psychological science and popular self-help advice.

Deconstructing Entrepreneurial Discovery

An adaption of a 2022 preprint article published in Technovation , this article explores how alertness might be related to entrepreneurial discovery and whether positivity or negativity are more associated with alertness.

Research Briefs

Recent highlights from APS journals articles on learning about the self, mental health interventions, representational momentum for physical states, and much more.

Privacy Overview

Why the Clock Counts with Critical Thinking

Timing matters when it comes to accepting extraordinary claims..

Posted September 24, 2023 | Reviewed by Devon Frye

Embracing a strong belief in the right thing at the wrong time is a deceptive victory.
Strange possibilities should not be ruled out.
The core power and most exciting aspect of science is not what we know now, but what we might learn next.
The best we can do is strive to be correct according to the best evidence available now.

It may seem counterintuitive, but being correct in the long run is not the only consideration when it comes to extraordinary claims. It’s a detail often missed, but when one decides to accept or believe something matters—even if it eventually proves true.

This is important to recognize because embracing a strong belief in the right thing at the wrong time is a deceptive victory. It can encourage overconfidence in unreliable hunches and obscure flawed and dangerous thinking processes, all of which are likely to create problems throughout life.

Consider the factor of timing regarding UFOs. Anyone who “knows” today that some of them are extraterrestrial visitors has had their mind probed and abducted by an irrational belief because there is nothing close to credible confirmation for it. But what if aliens were to land on the rooftop of the United Nations building tomorrow and confess that they have been buzzing us for decades?

UFO believers would say, “told you so,” and deservedly so. But their prior position still would have been the result of extraordinarily poor thinking skills. And those skills won’t improve without a personal reckoning that includes acknowledging the significance of timing and a new commitment to thinking before believing.

It would be no different if Bigfoot were captured or a quirk of quantum physics proved the claims of homeopathy. Feelings of vindication aside, the unjustified embrace of an extremely dubious position that later turns out to be correct is not much more impressive than that of a broken clock being precisely accurate twice per day. A supervolcano might choke out civilization next year, but it wouldn’t mean the guy on a street corner yelling, “The end is near,” knew what he was talking about.

Some will argue that being proven right over time is enough, regardless of how unjustified the conclusion or belief once was. But this ignores the dangers of habitual sloppy thinking. If skepticism and quality of evidence are unimportant for one claim, then what is the standard for others? If one believes the Apollo Moon landings were faked, why not trust a chiropractor to treat a serious health issue? If reflexology is valid, why not Assyrian haruspicy, too? Where does it end? Sadly, of course, there is no end for some who seem to live almost entirely in a state of cognitive chaos.

To help premature believers, advocates of critical thinking might add the role of timing to their list of essential talking points. I consistently emphasize to others that the safer and more efficient way to mentally navigate the world is to consistently side with the best knowledge currently available—and be prepared to change course the moment new evidence demands it. I also make a point to concede that a given extraordinary and unlikely claim could be true, but quickly add that it doesn’t matter if currently there are no good reasons to believe it.

I understand that this burden of waiting for sufficient evidence can be inconvenient or uncomfortable, but it is crucial when it comes to important and unusual claims. There are exceptions, of course. Sometimes the stakes are high, there is legitimate urgency, and a hunch is all you have. For example, if I’m walking in a dark alley and someone in the shadows appears to be waving a knife and seems to be whispering something about my wallet, I’m running and not hanging around for scientific confirmation. In most cases, however, we have the luxury of waiting to see if good evidence ever arrives.

Drawing attention to this timing component of critical thinking is not a blanket rejection of fringe ideas. It is important to consider unlikely things and maintain appropriate humility before strange possibilities. The core power and most exciting aspect of science is not what we know now, but what we might learn next. A nagging intuition , compelling flash of insight, or gut feeling can be a fruitful starting point toward spectacular discovery.

But the hunch itself is not enough, and certainly should not be the endpoint. For example, my love of science fiction and the compressed version of the Drake Equation that lives in my head biases me with a strong inclination to think that we are not alone in a universe with this much time, space, matter, and energy. But until SETI holds the greatest press conference in history, it would be an appalling breach of reason if I were to take any stance other than “I don’t know.” The critical-thinking clock is clear on this. It’s too early to be sure.

An important technical point is that waiting for sufficient evidence is not an absolute denial of the claim. Neither is it a sign of being closed-minded, the standard cheap shot lobbed at critical thinkers. I suppose it can feel like a contradiction, but good thinking demands that we c onsider anything and doubt everything .

The late astronomer Carl Sagan mentioned this in his book The Demon Haunted World : “As I’ve tried to stress , at the heart of science is an essential balance between two seemingly contradictory attitudes—an openness to new ideas, no matter how bizarre or counterintuitive, and the most ruthlessly skeptical scrutiny of all ideas, old and new. This is how deep truths are winnowed from deep nonsense.”

I have learned from experience that openly noting the possibility of improbable things can aid communication between believer and skeptic. I readily admit that giant primates and interstellar visitors are not impossible, only that declaring them to be real phenomena right now is a problem. It demonstrates the same kind of muddled judgment that leads people into dangerous medical quackery, financial scams, predatory organizations, and destructive political loyalties.

The best we can do is strive to be correct according to the best evidence available now . Mind the clock and keep steering toward the best current version of reality. Take positions that are most reasonable today . We can always change our minds tomorrow if the aliens land and say hello.

Guy P. Harrison is the author of Think: Why You Should Question Everything.

Find a Therapist
Find a Treatment Center
Find a Psychiatrist
Find a Support Group
Find Online Therapy
International
New Zealand
South Africa
Switzerland
Asperger's
Bipolar Disorder
Chronic Pain
Eating Disorders
Passive Aggression
Personality
Goal Setting
Positive Psychology
Stopping Smoking
Low Sexual Desire
Relationships
Child Development
Self Tests NEW
Therapy Center
Diagnosis Dictionary
Types of Therapy

At any moment, someone’s aggravating behavior or our own bad luck can set us off on an emotional spiral that threatens to derail our entire day. Here’s how we can face our triggers with less reactivity so that we can get on with our lives.

Emotional Intelligence
Gaslighting
Affective Forecasting
Neuroscience

Explained: Importance of critical thinking, problem-solving skills in curriculum

F uture careers are no longer about domain expertise or technical skills. Rather, critical thinking and problem-solving skills in employees are on the wish list of every big organization today. Even curriculums and pedagogies across the globe and within India are now requiring skilled workers who are able to think critically and are analytical.

The reason for this shift in perspective is very simple.

These skills provide a staunch foundation for comprehensive learning that extends beyond books or the four walls of the classroom. In a nutshell, critical thinking and problem-solving skills are a part of '21st Century Skills' that can help unlock valuable learning for life.

Over the years, the education system has been moving away from the system of rote and other conventional teaching and learning parameters.

They are aligning their curriculums to the changing scenario which is becoming more tech-driven and demands a fusion of critical skills, life skills, values, and domain expertise. There's no set formula for success.

Rather, there's a defined need for humans to be more creative, innovative, adaptive, agile, risk-taking, and have a problem-solving mindset.

In today's scenario, critical thinking and problem-solving skills have become more important because they open the human mind to multiple possibilities, solutions, and a mindset that is interdisciplinary in nature.

Therefore, many schools and educational institutions are deploying AI and immersive learning experiences via gaming, and AR-VR technologies to give a more realistic and hands-on learning experience to their students that hone these abilities and help them overcome any doubt or fear.

ADVANTAGES OF CRITICAL THINKING AND PROBLEM-SOLVING IN CURRICULUM

Ability to relate to the real world: Instead of theoretical knowledge, critical thinking, and problem-solving skills encourage students to look at their immediate and extended environment through a spirit of questioning, curiosity, and learning. When the curriculum presents students with real-world problems, the learning is immense.

Confidence, agility & collaboration : Critical thinking and problem-solving skills boost self-belief and confidence as students examine, re-examine, and sometimes fail or succeed while attempting to do something.

They are able to understand where they may have gone wrong, attempt new approaches, ask their peers for feedback and even seek their opinion, work together as a team, and learn to face any challenge by responding to it.

Willingness to try new things: When problem-solving skills and critical thinking are encouraged by teachers, they set a robust foundation for young learners to experiment, think out of the box, and be more innovative and creative besides looking for new ways to upskill.

It's important to understand that merely introducing these skills into the curriculum is not enough. Schools and educational institutions must have upskilling workshops and conduct special training for teachers so as to ensure that they are skilled and familiarized with new teaching and learning techniques and new-age concepts that can be used in the classrooms via assignments and projects.

Critical thinking and problem-solving skills are two of the most sought-after skills. Hence, schools should emphasise the upskilling of students as a part of the academic curriculum.

The article is authored by Dr Tassos Anastasiades, Principal- IB, Genesis Global School, Noida.

Watch Live TV in English

Watch Live TV in Hindi

Explained: Importance of critical thinking, problem-solving skills in curriculum

IMAGES

Why critical thinking is important
PPT
How to be Less Gullible
The benefits of critical thinking for students and how to develop it
Why is Critical Thinking Important?
The Importance Of Critical Thinking.

VIDEO

Why critical thinking is so important
Why is critical thinking important???#aesthetic #aesthetic introverts •.•
Critical Reading and Critical thinking?|Definition| Meaning|Process|Goals
Why knowledge must precede critical thinking
Why Critical Thinking Is So Important In Today's World @TheIcedCoffeeHour
Critical Thinking is All You Need To Build Business and Life (How To Think Critically)

COMMENTS

On Critical Thinking
Theoretical critical thinking involves helping the student develop an appreciation for scientific explanations of behavior. This means learning not just the content of psychology but how and why psychology is organized into concepts, principles, laws, and theories. Developing theoretical skills begins in the introductory course where the ...
Critical Thinking: A Model of Intelligence for Solving Real-World
4. Critical Thinking as an Applied Model for Intelligence. One definition of intelligence that directly addresses the question about intelligence and real-world problem solving comes from Nickerson (2020, p. 205): "the ability to learn, to reason well, to solve novel problems, and to deal effectively with novel problems—often unpredictable—that confront one in daily life."
Why is critical thinking important for Psychology students?
Critical thinking is objective and requires you to analyse and evaluate information to form a sound judgement. It is a cornerstone of evidence-based arguments and forming an evidence-based argument is essential in Psychology. That is why we, your tutors, as well as your future employers, want you to develop this skill effectively.
A Brief Guide for Teaching and Assessing Critical Thinking in Psychology
One motivational strategy is to explain why CT is important to effective, professional behavior. Often, telling a compelling story that illustrates the consequences of failing to think critically can motivate students. ... Perspectives on Psychological Science, 2, 53-70. ... Critical thinking in psychology: Separating sense from nonsense ...
A Crash Course in Critical Thinking
Here is a series of questions you can ask yourself to try to ensure that you are thinking critically. Conspiracy theories. Inability to distinguish facts from falsehoods. Widespread confusion ...
On Critical Thinking
North Carolina. "The real value of being a good critical thinker in psychology is so you won't be a jerk," he said with a smile. That observation remains one of my favorites in justifying why teaching critical thinking skills should be an important goal in psychology. However, I believe it captures only a
Frontiers
Scientific thinking is the ability to generate, test, and evaluate claims, data, and theories (e.g., Bullock et al., 2009; Koerber et al., 2015 ). Simply stated, the basic tenets of scientific thinking provide students with the tools to distinguish good information from bad. Students have access to nearly limitless information, and the skills ...
Critical Thinking
Diane F. Halpern defined critical thinking as an attempt to increase the probability of a desired outcome (e.g., making a sound decision, successfully solving a problem) by using certain cognitive skills and strategies. Critical thinking is more than just a collection of skills and strategies: it is a disposition toward engaging with problems.
PDF Thinking Critically with Psychological Science
Hypothesis. A Hypothesis is a testable prediction, often prompted by (derived from) a theory, or inferred from observing behaviors, to enable us to accept, reject or revise the theory. Deductive: Derived from Theory (top down) vs Inductive: Derived from Observation (bottom up) 19. Experimentation.
Critical Thinking in Psychology
Good scientific research depends on critical thinking at least as much as factual knowledge; psychology is no exception to this rule. And yet, despite the importance of critical thinking, psychology students are rarely taught how to think critically about the theories, methods, and concepts they must use.
PDF Critical Thinking in Psychology
This book is an introductory text on critical thinking for upper-level undergraduates and graduate students. It shows students how to think critically about key topics such as experimental research, statistical inference, case studies, logical fallacies, and ethical judgments. Robert J. Sternberg is Dean of Arts and Sciences at Tufts University.
Critical thinking in psychology, 2nd ed.
This book presents essays by some of the foremost experts on critical thinking in the field of psychology. It is oriented toward students of psychology who hope to learn how to improve their critical thinking skills, and also to instructors who seek to teach and assess for critical thinking. Good scientific research depends on critical thinking at least as much as factual knowledge; psychology ...
Unit 04: How to Think Critically about Psychological Science
To appreciate why critical thinking is crucial to understanding psychological science, Watch Crash Course's (2014) YouTube, " Psychological Research . " Because the narrator of the video speaks quite rapidly, you might need to watch the video at least twice (or use the speed-controller in the settings options on YouTube).
Understanding the Complex Relationship between Critical Thinking and
The findings support the important role of the critical-thinking skill of inference in scientific reasoning in writing, while also highlighting ways in which other aspects of science reasoning (epistemological considerations, writing conventions, etc.) are not significantly related to critical thinking.
What Are Critical Thinking Skills and Why Are They Important?
It makes you a well-rounded individual, one who has looked at all of their options and possible solutions before making a choice. According to the University of the People in California, having critical thinking skills is important because they are [ 1 ]: Universal. Crucial for the economy. Essential for improving language and presentation skills.
The Importance Of Critical Thinking, and how to improve it
Critical thinking can help you better understand yourself, and in turn, help you avoid any kind of negative or limiting beliefs, and focus more on your strengths. Being able to share your thoughts can increase your quality of life. 4. Form Well-Informed Opinions.
Thinking critically on critical thinking: why scientists' skills need
A key part of this is critical thinking. It's a skill that often feels in short supply these days, but you don't necessarily need to study science or maths in order gain it.
PDF Thinking Critically With Psychological Science
Psychological Science OUTLINE OF RESOURCES NOTE: Several activities (indicated by a †) may be appropriate for use with topics other than the one for which they ... Critical Thinking and the Scientific Method Lecture/Discussion Topics: Your Teaching Strategies and Critical Thinking† (p. ... reinforce the important methodological differences ...
Cognitive Psychology: The Science of How We Think
MaskotOwner/Getty Images. Cognitive psychology involves the study of internal mental processes—all of the workings inside your brain, including perception, thinking, memory, attention, language, problem-solving, and learning. Cognitive psychology--the study of how people think and process information--helps researchers understand the human brain.
Critical thinking, science, and pseudoscience: Why we can't trust our
Rather than merely focusing on critical thinking, the text incorporates the perspectives of psychology, biology, physics, medicine, and other disciplines to reinforce different categories of rational explanation. Accessible and engaging, it describes what critical thinking is, why it is important, and how to learn and apply skills that promote it.
Critical Thinking in Science
Critical thinking in science is important largely because a lot of students have developed expectations about science that can prove to be counter-productive. ... Handbook of child psychology, Vol. 4. Wiley. A review of research on scientific thinking and experiments on teaching scientific thinking in the classroom.
Teaching: On the Benefits of Critical Ignoring
To foster such understanding, psychological scientists teach critical thinking. Using the scientific method, students learn how to approach competing ideas with an analytical mindset—leading them to rely on evidence rather than anecdote or intuition. According to Anastasia Kozyreva, Sam Wineburg, and APS Fellows Stephan Lewandowsky and Ralph ...
Why the Clock Counts with Critical Thinking
When we believe is a crucial component of critical thinking because it reveals much about how we think. Source: Guy P. Harrison. It may seem counterintuitive, but being correct in the long run is ...
Practice for knowledge acquisition (not drill and kill)
Deliberate practice involves attention, rehearsal and repetition and leads to new knowledge or skills that can later be developed into more complex knowledge and skills. Although other factors such as intelligence and motivation affect performance, practice is necessary if not sufficient for acquiring expertise (Campitelli & Gobet, 2011).
Misinformation and disinformation
Misinformation is false or inaccurate information—getting the facts wrong. Disinformation is false information which is deliberately intended to mislead—intentionally misstating the facts. The spread of misinformation and disinformation has affected our ability to improve public health, address climate change, maintain a stable democracy ...
Cognitive psychology
Cognitive psychology is the scientific study of mental processes such as attention, language use, memory, perception, problem solving, creativity, and reasoning.. Cognitive psychology originated in the 1960s in a break from behaviorism, which held from the 1920s to 1950s that unobservable mental processes were outside the realm of empirical science.. This break came as researchers in ...
Critical thinking in primary science through a guided inquiry pedagogy
Although education research in critical thinking is a rapidly emerging field, how teachers can facilitate, monitor, and support critical thinking in primary science remains a challenge. This paper builds on recent semiotics mediated scientific reasoning research to present a fresh perspective of critical thinking in primary science. Analysis of student and teacher interactions in an innovated ...
What Is Critical Thinking and Why Is It Important?
Professional spaces: Critical thinking helps you to learn and sort through new information and develop innovative solutions to the problems you are faced with. This skill is necessary for every role, but especially for leadership positions. When faced with challenges in your career, critical thinking can help you see situations clearly and make ...
Confirmation bias
Confirmation bias (also confirmatory bias, myside bias, or congeniality bias) is the tendency to search for, interpret, favor, and recall information in a way that confirms or supports one's prior beliefs or values. People display this bias when they select information that supports their views, ignoring contrary information, or when they interpret ambiguous evidence as supporting their ...
Explained: Importance of critical thinking, problem-solving skills in
Confidence, agility & collaboration. : Critical thinking and problem-solving skills boost self-belief and confidence as students examine, re-examine, and sometimes fail or succeed while attempting ...