Abstract
In recent years, there has been an increased interest in conceptual blending in physics and mathematics education research as a theoretical framework to study student reasoning. In this paper, we adapt the conceptual blending framework to construct a blending diagram that not only captures the product but also the process of student reasoning when they interpret a mathematical description of a physical system. We describe how to construct a dynamic blending diagram (DBD) and illustrate this using two cases from an interview study. In the interview, we asked pairs of undergraduate physics and mathematics students about the physical meaning of boundary conditions for the heat equation. The selected examples show different aspects of the DBD as an analysis method. We show that by using a DBD, we can judge the degree to which students integrate their understandings of mathematics and physics. The DBD also enables the reader to follow the line of reasoning of the students. Moreover, a DBD can be used to diagnose difficulties in student reasoning.
Highlights
Interpreting the way students use and understand the mathematics used in physics is an important and central research theme in physics education research (PER) (e.g., Refs. [1,2,3,4,5,6,7,8,9])
We use the conceptual blending framework as a lens to study student thinking while combining mathematics and physics in the context of phenomena described by the heat equation
We propose the dynamic blending diagram as a way to analyze student reasoning
Summary
Interpreting the way students use and understand the mathematics used in physics is an important and central research theme in physics education research (PER) (e.g., Refs. [1,2,3,4,5,6,7,8,9]). Interpreting the way students use and understand the mathematics used in physics is an important and central research theme in physics education research (PER) Proficiency in mathematics is required to describe and understand physical phenomena, and being able to combine the different fields is a prerequisite to become more proficient in physics. Understanding an equation in physics goes beyond connecting the symbols to physical quantities and being able to perform calculations and operations with that equation. It involves being able to connect mathematical knowledge and representations to physical meaning and integrating an equation with its implications in the physical world [10]. Parsing students’ mathematical and physical understanding has proven challenging as the use of mathematics in physics
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