Framework for Understanding the Patterns of Student Difficulties in Quantum Mechanics

Autor/inn/en	Marshman, Emily; Singh, Chandralekha
Titel	Framework for Understanding the Patterns of Student Difficulties in Quantum Mechanics
Quelle	In: Physical Review Special Topics - Physics Education Research, 11 (2015) 2, S.020119-1 (26 Seiten) PDF als Volltext Verfügbarkeit
Sprache	englisch
Dokumenttyp	gedruckt; online; Zeitschriftenaufsatz
ISSN	1554-9178
DOI	10.1103/PhysRevSTPER.11.020119
Schlagwörter	Science Instruction; Quantum Mechanics; Mechanics (Physics); Logical Thinking; Scientific Concepts; Concept Formation; College Students; Student Motivation; Readiness; Problem Solving; Teaching Methods; College Science; Introductory Courses; Classification; Transfer of Training; Barriers; Epistemology; Vocabulary; Beliefs + Suchen Sie Ihr Suchwort? Teaching of science; Science education; Natural sciences Lessons; Naturwissenschaftlicher Unterricht; Quantenmechanik; Mechanik; Concept learning; Begriffsbildung; Collegestudent; Schulische Motivation; Problemlösen; Teaching method; Lehrmethode; Unterrichtsmethode; Einführungskurs; Classification system; Klassifikation; Klassifikationssystem; Training; Transfer; Ausbildung; Erkenntnistheorie; Wortschatz; Belief; Glaube
Abstract	Compared with introductory physics, relatively little is known about the development of expertise in advanced physics courses, especially in the case of quantum mechanics. Here, we describe a framework for understanding the patterns of student reasoning difficulties and how students develop expertise in quantum mechanics. The framework posits that the challenges many students face in developing expertise in quantum mechanics are analogous to the challenges introductory students face in developing expertise in introductory classical mechanics. This framework incorporates both the effects of diversity in upper-level students' prior preparation, goals, and motivation in general (i.e., the facts that even in upper-level courses, students may be inadequately prepared, have unclear goals, and have insufficient motivation to excel) as well as the "paradigm shift" from classical mechanics to quantum mechanics. The framework is based on empirical investigations demonstrating that the patterns of reasoning, problem-solving, and self-monitoring difficulties in quantum mechanics bear a striking resemblance to those found in introductory classical mechanics. Examples from research in quantum mechanics and introductory classical mechanics are discussed to illustrate how the patterns of difficulties are analogous as students learn to unpack the respective principles and grasp the formalism in each knowledge domain during the development of expertise. Embracing such a framework and contemplating the parallels between the difficulties in these two knowledge domains can enable researchers to leverage the extensive literature for introductory physics education research to guide the design of teaching and learning tools for helping students develop expertise in quantum mechanics. [This paper is part of the Focused Collection on Upper Division Physics Courses.] (As Provided).
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Erfasst von	ERIC (Education Resources Information Center), Washington, DC
Update	2020/1/01