Teaching critical thinking

The ability to make decisions based on data, with its inherent uncertainties and variability, is a complex and vital skill in the modern world. The need for such quantitative critical thinking occurs in many different contexts, and although it is an important goal of education, that goal is seldom b...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 112; no. 36; pp. 11199 - 11204
Main Authors Holmes, N. G., Wieman, Carl E., Bonn, D. A.
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 08.09.2015
National Acad Sciences
SeriesFrom the Cover
Subjects
Algorithms
Critical thinking
Decision making
Decision Making - physiology
Educational Measurement
Experiments
Feedback
Humans
Physics - education
Reproducibility of Results
Research - education
Social Sciences
Students - psychology
Teaching
Teaching - methods
Thinking - physiology
Universities
critical thinking
undergraduate education
scientific reasoning
teaching experimentation
scientific teaching
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Summary:The ability to make decisions based on data, with its inherent uncertainties and variability, is a complex and vital skill in the modern world. The need for such quantitative critical thinking occurs in many different contexts, and although it is an important goal of education, that goal is seldom being achieved. We argue that the key element for developing this ability is repeated practice in making decisions based on data, with feedback on those decisions. We demonstrate a structure for providing suitable practice that can be applied in any instructional setting that involves the acquisition of data and relating that data to scientific models. This study reports the results of applying that structure in an introductory physics laboratory course. Students in an experimental condition were repeatedly instructed to make and act on quantitative comparisons between datasets, and between data and models, an approach that is common to all science disciplines. These instructions were slowly faded across the course. After the instructions had been removed, students in the experimental condition were 12 times more likely to spontaneously propose or make changes to improve their experimental methods than a control group, who performed traditional experimental activities. The students in the experimental condition were also four times more likely to identify and explain a limitation of a physical model using their data. Students in the experimental condition also showed much more sophisticated reasoning about their data. These differences between the groups were seen to persist into a subsequent course taken the following year.
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Author contributions: N.G.H., C.E.W., and D.A.B. designed research; N.G.H. and D.A.B. performed research; N.G.H. analyzed data; and N.G.H., C.E.W., and D.A.B. wrote the paper.
Edited by Samuel C. Silverstein, College of Physicians and Surgeons, New York, NY, and accepted by the Editorial Board July 14, 2015 (received for review March 17, 2015)
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1505329112