Teacher Re-novicing on the Path to Integrating Computational Thinking in High School Physics Instruction-Reference-Cited by-同舟云学术

Teacher Re-novicing on the Path to Integrating Computational Thinking in High School Physics Instruction

Published:2023-06-14 Issue:2 Volume:6 Page:302-325
ISSN:2520-8705
Container-title:Journal for STEM Education Research
language:en
Short-container-title:Journal for STEM Educ Res

Author:

Lane W. Brian^ORCID,Galanti Terrie M.^ORCID,Rozas X. L.^ORCID

Abstract

AbstractIntegrating computational thinking (CT) into STEM disciplines requires secondary teachers to develop their pedagogical content knowledge of computing and content integration. Experienced teachers who choose to integrate CT in their secondary STEM courses may struggle in the same ways as novice teachers as they learn about programming and its potential use within their content areas. This study describes these potential struggles as teacher re-novicing in the context of high school physics. The research team facilitated a week-long computing integration workshop for physics teachers (n = 24) from three countries. The teachers engaged with computational learning activities in Jupyter Notebooks with the goal of developing their capacity to integrate Python in physics applications. Qualitative analysis of teacher surveys supported our theorization of a pathway of CT integration knowledge development. We describe these professional learning needs in four illustrative cases, building a grounded theory for teacher re-novicing as a pathway beginning with computing knowledge, moving through physics applications of computing, and arriving at pedagogical knowledge for physics-CT integration.

Funder

Voya Foundation

American Institute of Physics

Publisher

Springer Science and Business Media LLC

Subject

Energy Engineering and Power Technology,Fuel Technology

Link

https://link.springer.com/content/pdf/10.1007/s41979-023-00100-1.pdf

Reference57 articles.

1. Backer, A. (2007). Computational physics education with Python. Computing in Science & Engineering, 9(3), 30–33. https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=4160252.

2. Barber, J. P., & Walczak, K. K. (2009). Conscience and critic: Peer debriefing strategies in grounded theory research. [Paper presentation]. San Diego, CA: American Educational Research Association Annual Meeting.

3. Barr, D., Harrison, J., & Conery, L. (2011). Computational thinking: A digital age skill for everyone. Learning and Leading with Technology, 38(6), 20–23.

4. Beheshti, E., Weintrop, D., Swanson, H., Orton, K., Horn, M. S., Jona, K., & Wilensky, U. (2017). Computational thinking in practice: How STEM professionals use CT in their work. [Paper presentation]. American Educational Research Association (AERA) Annual Meeting. https://par.nsf.gov/servlets/purl/10026245.

5. Biddy, Q., Chakarov, A. G., Bush, J., Elliott, C. H., Jacobs, J., Recker, M., Summner, T., & Penuel, W. (2021). A professional development model to integrate computational thinking into middle school science through codesigned storylines. Contemporary Issues in Technology and Teacher Education, 21(1), 53–96. https://www.learntechlib.org/p/216072/.

Cited by 2 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Math+CS: Comparing Teaching Candidates in a Methods Course and Pre-Service Teachers in a Math and Technology Course;2023 IEEE Frontiers in Education Conference (FIE);2023-10-18

2. STRUCTURAL-FUNCTIONAL MODEL OF TEACHING PHYSICAL AND TECHNICAL DISCIPLINES BASED ON STEM EDUCATION: THE ASPECT OF TRANSDISCIPLINARITY;Scientific Notes of Junior Academy of Sciences of Ukraine;2023