Complexity Theory and Physics Education Research : The Case of Student Retention in Physics and Related Degree Programmes

Forsman, Jonas

January 2015

This thesis explores the use of complexity theory in Physics Education Research as a way to examine the issue of student retention (a university’s ability to retain its students). University physics education is viewed through the concepts of nestedness and networked interactions. The work presented in this thesis covers two main aspects from a complexity theory perspective: (1) institutional action to enhance student retention; and, (2) the role of students’ in-course interaction networks. These aspects are used to reframe student retention from a complexity theory perspective, as well as to explore what implications this new perspective affords. The first aspect is addressed by conceptualizing student retention as an emergent phenomenon caused by both agent and component interaction within a complex system. A methodology is developed to illustrate a networked visualization of such a system using contemporary estimation methods. Identified limitations are discussed. To exemplify the use of simulations of complex systems, the networked system created is used to build a simulation of an “ideal” university system as well as a Virtual world for hypothesis-testing. The second aspect is divided into two sections: Firstly, an analysis of processes relating to how students’ in-course networks are created is undertaken. These networks are divided into two relevant components for student retention – the social and the academic. Analysis of these two components of the networks shows that the formation of the networks is not a result of random processes and is thus framed as a function of the core constructs of student retention research – the social and academic systems. Secondly, a case is made that students’ structural positions in the social and academic networks can be related to their grade achievement in the course.

Physics Education Research

Complexity Theory

Student Retention

Modeling and Assessing Knowledge Integration: Development of the Conceptual Framework Representation

Fritchman, Joseph C.

January 2020

No description available.

Physics

Physics Education Research

Knowledge Integration

Mixed methods Analysis of Undergraduate Quantum Mechanics: An Exploratory Case Study

Oakley, Christopher A.

18 December 2013

One key goal of Physics Education Research is providing research-based instructional techniques and tools to help assess the complex learning goals associated with a mature understanding of physics. Characterizing faculty expectations is important to produce a comprehensive understanding of knowledge students should acquire before and during a quantum mechanics course (QMC). Semi-structured interviews have been conducted with faculty members and students entering a QMC in the Physics Program at a Large Public Research University (LPRU) in the Southeast. The interviews examine perspectives of different evaluation techniques, ideal preparation, course content, and expected conceptual models of students. A post-course survey was offered to the students that took the QMC in the Fall of 2012 and to those who completed the course in the past three years. The survey addressed similar questions on evaluation, course content, and preparation. Using Classical Content Analysis and Key-Words-In-Context coding methods, contradictions and similarities within and between faculty and student populations are presented. These results are presented in an effort to highlight predictors for success in the QMC, identify “common-core” perceptions, and strengthen course evaluation. In all data, findings suggest that student perceptions shift towards those of faculty over the course of the QMC. Evaluation data indicate that on average the faculty members, like students, are open to a varied array of evaluation techniques, if it is within the goals of the course and does not interfere with other faculty responsibilities. In perceptions of preparation and course content, faculty have a uniform perspective of what should be prerequisite, and the student survey data strongly recommend that the second semester of Linear Algebra offered at the LPRU will help with the mathematical complexities of the QMC. Through triangulation of qualitative and quantitative results contradictions of preparation and content are exhibited through multiple media for the use course content such as the Hamiltonian.

Physics education research

Quantum mechanics

Mixed methods

Evaluation

Qualitative analysis

Student Reasoning from Data Tables: Data Interpretation in Light of Student Ability and Prior Belief

Bogdan, Abigail Marie

22 September 2016

No description available.

Physics

physics education research

control of variables

scientific reasoning

Social Network Analysis and the Representation of Female Students in Introductory Undergraduate Physics

Hierath, Sarah Teresa

19 August 2016

No description available.

Physics

Physics Education Research

Social Network Analysis

Gender

How Are Learning Physics And Student Beliefs About Learning Physics Connected? Measuring Epistemological Self-Reflection In An Introductory Course And Investigating Its Relationship To Conceptual Learning

May, David B.

11 September 2002

No description available.

epistemological beliefs

physics

conceptual understanding

reflection

Physics Education Research

Comparing the scaffolding provided by physical and virtual manipulative for students' understanding of simple machines

Chini, Jacquelyn J.

January 1900

Doctor of Philosophy / Department of Physics / Nobel S. Rebello / Conventional wisdom has long advised that students’ learning is best supported by interaction with physical manipulative. Thus, in the physics laboratory, students typically spend their time conducting experiments with physical equipment. However, computer simulations offer a tempting alternative to traditional physical experiments. In a virtual experiment, using a computer simulation, students can gather data quickly, and measurement errors and frictional effects can be explicitly controlled. This research investigates the relative support for students’ learning offered by physical and virtual experimentation in the context of simple machines. Specifically, I have investigated students’ learning as supported by experimentation with physical and virtual manipulative from three different angles-- what do students learn, how do students learn, and what do students think about their learning. The results indicate that the virtual manipulative better supported students’ understanding of work and potential energy than the physical manipulative did. Specifically, in responding to data analysis questions, students who used the virtual manipulative before the physical manipulative were more likely to describe work as constant across different lengths of frictionless inclined planes (or pulley systems) and were more likely to adequately compare work and potential energy, whereas students who used the physical manipulative first were more likely to talk about work and potential energy separately. On the other hand, no strong support was found to indicate that the physical manipulative better supported students’ understanding of a specific concept. In addition, students’ responses to the survey questions indicate that students tend to value data from a computer simulation more than from a physical experiment. The interview analysis indicates that the virtual environment better supported the students to create new ideas than the physical environment did. These results suggest that the traditional wisdom that students learn best from physical experiments is not necessarily true. Thus, researchers should continue to investigate how to best interweave students’ experiences with physical and virtual manipulatives. In addition, it may be useful for curriculum designers and instructors to spend more of their efforts designing learning experiences that make use of virtual manipulatives.

Physics education research

Student understanding

Simulation

Traditional laboratory

Simple machines

Education, Sciences (0714)

Physics, General (0605)

The Impact of Collaboration Between Science and Education Faculty Members on Teaching for Conceptual Change: A Phenomenographic Case Study of a Physics Professor

Stoll, William A., III

08 January 2016

This dissertation presents a phenomenographic case study of a senior physics professor during and beyond an extended collaboration with a science education professor from a College of Education. The context for the collaboration is the co-teaching of a physics course for graduate students in a Masters of Teaching program at a research university in the southeastern US. The course was focused on physics content and the pedagogy of teaching for conceptual change. The purpose of this study is to investigate from a physics professor’s perspective the progression of his conceptions and practices regarding teaching for conceptual change over the duration of the collaboration and beyond. Prior research indicates that such change is a difficult and complex process requiring a transformative, personal experience. Collaboration between science departments and Colleges of Education has been identified as a key opportunity for transformative experiences, but research on the resulting changes is limited. Questions addressed by this study include (a) what is the evidence of change in a physics professor’s conceptions of teaching for conceptual change, (b) what is the evidence of change in a physics professor’s practices of teaching for conceptual change, (c) what are the learning environment characteristics identified by the physics professor that either facilitated or hindered changes in his conceptions and/or practices in teaching for conceptual change. The primary data were interviews with the physics professor integrated with direct classroom observations. Emergent categories of how the physics professor conceived and practiced teaching for conceptual change showed a progression over time toward a more expert view on teaching for conceptual change. Key factors identified in the physics professor’s progression are: 1) his motivation to become a more effective teacher, 2) the expertise of the science education professor, and 3) the way the collaboration developed. Limiting factors identified include: 1) time pressure for content coverage, 2) difficulty in translating change to other contexts, and 3) unsupportive external environments.

Teaching for Conceptual Change

Teacher learning

Teacher change

Collaboration

Phenomenography

Physics Education Research

Examining Students' Representation Choices in University Modeling Instruction

McPadden, Daryl

20 March 2018

Representations (such as pictures, diagrams, word descriptions, equations, etc.) are critical tools for learning, problem solving, and communicating in science, particularly in physics where multiple representations often serve as intermediate steps, a means to evaluate a solution, and highlight different aspects a physical phenomenon. This dissertation explores the representation choices made by students in the University Modeling Instruction (MI) courses on problems from across introductory physics content. Modeling Instruction is a two-semester introductory, calculus-based physics sequence that was designed to guide students through the process of building, testing, applying, and refining models. As a part of this modeling cycle, students have explicit instruction and practice in building, evaluating, and coordinating representations in introductory physics. Since I am particularly interested in representations across all of introductory physics, this work was situated in the second semester of MI. To address students' representation choices, the Problem Solving and Representation Use Survey (PSRUS) was developed as modified card sort survey, which asked students to simply list the representations that they would use on 25 physics questions from across introductory physics. Using non-parametric statistical tests (Mann-Whitney-Wilcox, Wilcoxon-Ranked Sign, and Cliff's Delta), I compare the number and variety of representations that students choose. Initially, students who took the first semester of MI use significantly more representations in their problem solving when compared to those who did not; however, there are significant gains in the number of representations that these students choose over the semester across the introductory physics content. After significant changes to the second semester MI curriculum, the difference between these two groups disappears, with both groups increasing their representation choices when compared to the previous semester. Using network analysis to compare students' concurrent representation choices, I also show that students use a consistent set of representations on mechanics problems; whereas, they choose a wider variety on electricity and magnetism (EM) problems. In both mechanics and EM, pictures serve as an important connecting representation between the others. I use these results to make suggestions for instructors, curriculum developers, and physics education researchers.

Physics Education Research

Multiple Representations

Modeling Instruction

Curriculum and Instruction

Other Physics

Bilder av fysik : En studie om fysik på gymnasiet

Lantz, Jonn

January 2007

I detta arbete så vill jag studera hur praktisk fysikundervisning och bedömning i några svenska gymnasieskolor överensstämmer med modern forskning om fysikpedagogik. Denna forskning spänner över ett brett spektrum av metoder och teorier, varav jag har fokuserat på om lärarnas undervisning kan beskrivas som -elevaktiv eller inte, -mer eller mindre baserad på bokstudier, -inriktad på konceptuell förståelse eller mer förmågan att räkna specifika uppgifter. Dessa aspekter diskuteras även i relation till de inblandade lärarnas utbildning. För att kunna jämföra de olika klasserna och lärarna har jag använt ett test av konceptuell förståelse (FCI, se sektion 3.2) samt enkäter till lärare och elever. Ur ett tyvärr skevt urval av klasser och lärare framgår att det finns stora skillnader på hur lärarna ser på undervisningen och vilka undervisningsmetoder de använder, samt hur styrt de upplever sitt arbete. Korrelationerna mellan elevernas resultat på FCI och på ordinarie prov på motsvarande mekanik är små, vilket tyder på att reguljära prov mäter konceptuell förståelse i liten utsträckning. Det finns även skillnader i resultaten i form av elevernas konceptuella förståelse mellan skolorna, i linje med tidigare forskningsresultat att nyare metoder faktiskt ger bättre resultat, även om denna preliminära studie inte förmår ge underlag för direkta slutsatser. Resultaten tyder även preliminärt på att manliga elever lyckas få en bättre konceptuell förståelse än kvinnliga elever i skolan.

Physics education research

interactive engagement

Fysikpedagogik

Fysik

elevaktivt lärande

variationsteori

interaktiv undervisning

Pedgogical work

Pedagogiskt arbete