The design and development of a new method for high school physics instruction is described. Students are actively engaged in understanding the physical world by constructing and using scientific models to describe, explain, predict, and to control physical phenomena. Course content is organized around a small set of basic models. Instruction is organized into modeling cycles which move students systematically through all phases of model development, evaluation, and application in concrete situations—thus developing skill and insight in the procedural aspects of scientific knowledge. Objective evidence shows that the modeling method can produce much larger gains in student understanding than alternative methods of instruction. This reveals limitations of the popular ‘‘cooperative inquiry’’ and ‘‘learning cycle’’ methods. It is concluded that the effectiveness of physics instruction depends heavily on the pedagogical expertise of the teacher. The problem of cultivating such expertise among high school teachers is discussed at length, with specific recommendations for action within the physics community.
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July 1995
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July 01 1995
A modeling method for high school physics instruction
Malcolm Wells;
Malcolm Wells
Department of Physics and Astronomy, Box 871504, Arizona State University, Tempe, Arizona 85287‐1504
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David Hestenes;
David Hestenes
Department of Physics and Astronomy, Box 871504, Arizona State University, Tempe, Arizona 85287‐1504
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Gregg Swackhamer
Gregg Swackhamer
Glenbrook North High School, 2300 Shermar Road, Northbrook, Illinois 60062
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Am. J. Phys. 63, 606–619 (1995)
Article history
Received:
September 21 1994
Accepted:
December 31 1994
Citation
Malcolm Wells, David Hestenes, Gregg Swackhamer; A modeling method for high school physics instruction. Am. J. Phys. 1 July 1995; 63 (7): 606–619. https://doi.org/10.1119/1.17849
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