Document Type : Original Research Paper-English Issue

Authors

Department of Physics Education, Farhangian University, P.O. Box 14665-889, Tehran, Iran

Abstract

Background and Objectives: The topic of electricity is often considered a challenging and abstract concept in physics. Learning non-intuitive scientific concepts can be challenging for students because they often hold incorrect conceptions about natural phenomena that lead them toward errors. Many students struggle to understand the underlying principles and behaviors of electrical systems. Identifying and correcting misconceptions about electricity physics is essential for promoting meaningful learning and conceptual understanding. Nowadays, using technology in educational settings is considered an essential aspect of teaching and learning. Utilizing technology, such as simulation software like COMSOL, can help to visualize and better understand these concepts. This research has been done with the aim of identifying and correcting the misunderstandings of 11th-grade high school students in learning the concepts of electricity by simulating COMSOL software.
Materials and Methods: The present research is an applied study in terms of its objective and a mixed-methods research in terms of its methodology. The qualitative section utilized content analysis to extract misconceptions about the concepts of electricity in physics. Semi-structured interviews were conducted with SIX teachers using purposive sampling. Three types of coding, namely open, axial, and selective, were employed to extract the main misconceptions. The main misconceptions identified were Coulomb's law, the shape of field lines between two point charges, the electric field between capacitor plates, the motion of electric charges in an external electric field, charge distribution on surfaces, and the effect of an external electric field on conductive and non-conductive shells. Based on this pattern, a 6-item questionnaire was designed to validate the pattern of misconceptions about electricity concepts among students. The validation of the extracted pattern and the content validity of the questionnaire were assessed by experts in the field of physics education. The quantitative section of the research was a quasi-experimental study with a pretest-posttest design and a control group. The target population consisted of all male eleventh-grade students in high schools in Bojnurd city during the academic year 2022-2023. Using random sampling, 30 students were selected for each group. In the first stage, both groups took a pretest. Then, the experimental group received the independent variable (simulation-based learning using the COMSOL software) in six sessions of 90 minutes each. Meanwhile, the control group received traditional lecture-based instruction. After the intervention, both groups (experimental and control) took the dependent variable (the misconceptions test on electricity concepts). The data were analyzed using ANCOVA (Analysis of Covariance) with the help of SPSS software.  
Findings: The post-test results showed that in addition to correcting students' misconceptions and increasing their learning level, the use of computer and COMSOL simulation software helped them better understand the concepts and increased their concentration. The results of this analysis showed a significant difference (p<0.05) between the learning and progress of the experimental group and the control group. The errors of the experimental group changed significantly compared to the control group.  In the topics under investigation, the minimum percentage of misconception correction in the experimental group was 46.66%. Meanwhile, the minimum percentage of misconception correction in the control group was observed to be 36.66%.
Conclusions: The research results have demonstrated that Simulation software enables students to visualize and interact with abstract concepts, making them more tangible and easier to comprehend. By using COMSOL, students can manipulate different variables in electrical systems, observe the effects, and gain insights into the underlying principles. This hands-on approach can correct misconceptions and improve students' understanding of electricity in physics. By providing interactive and visual representations of electrical phenomena, simulation software can make the subject more accessible and engaging, leading to improved learning outcomes. According to the obtained results, it is suggested that educational technology and modeling using COMSOL software be promoted in teachers' professional development programs. This action can lead to the development of knowledge of educational content and the correction of misunderstandings of concepts.

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© 2025 The Author(s).  This is an open-access article distributed under the terms and conditions of the Creative Attribution-NonCommercial 4.0 International (CC BY-NC 4.0) (https://creativecommons.org/licenses/by-nc/4.0/)  

https://doi.org/10.1063/5.0122687
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