The objective of this study is to examine the students’ purposes in conducting thought experiments while solving physics problems. There were 12 pre- and in-service physics teachers as the participants in this study and divided into three groups with four students in each. Physics problem-solving activities were used as a context for observing students’ processes in doing TEs. The results of the data analysis showed that there were three types of purposes of the students in doing the TEs during physics problem-solving activities: prediction, verification, and explanation. Therefore, it can be concluded that in the context of problem-solving, students design and run thought experiments as a creative ability tool to (1) predict solutions to the problem, (2) verify whether their hypothesis is correct or incorrect, (3) provide a detailed explanation to their hypothesis. Based on this study, we discuss the differences and similarities in the purposes of scientists and students in doing thought experiments. The importance and implications of thought experiments for current and future physics teachers are also discussed in the last part of this study

physics teacher; problem-solving; purpose; thought experiment

Arfini, S., Casadio, C., & Magnani, L. (2019). Ignorance preserving mental models thought experiments as abductive metaphors. Foundations of Science, 24, 391–409.

Asikainen, M. A., & Hirvonen, P. E. (2014). Probing pre- and in-service physics teachers’ knowledge using the double-slit thought experiment. Science & Education, 23, 1811–1833.

Bancong, H., & Song, J. (2018). Do physics textbooks present the ideas of thought experiments?: A case in Indonesia. Jurnal Pendidikan IPA Indonesia, 7(1), 25–33.

Bancong, H., & Song, J. (2020a). Factors triggering thought experiments in small group physics problem-solving activities. New Physics: Sae Mulli, 70(5), 466–480.

Bancong, H., & Song, J. (2020b). Exploring how students construct collaborative thought experiments during physics problem-solving activities. Science & Education, 29(3), 617-645.

Brown, J. R. (1991). The laboratory of the mind: thought experiments in the natural sciences. New York, NY: Routledge.

Brown, J. R. (2006). The promise and perils of thought experiments. Interchange, 37(1–2), 63–75.

Buzzoni, M. (2013). On thought experiments and the Kantian a priori in the natural sciences: A reply to Yiftach J.H. Fehige. Epistemologia, 36(2), 277–293.

Buzzoni, M. (2019). Thought experiments in philosophy: A neo-Kantian and experimentalist point of view. Topoi, 38(4), 771–779.

Cameron, R. P. (2015). Improve your thought experiments overnight with speculative fiction! Midwest Studies in Philosophy, 39(1), 29-45.

Clement, J. J. (2009). The role of imagistic simulation in scientific thought experiments. Topics in Cognitive Science, 1(4), 686–710.

Einstein, A. (1905). On the electrodynamics of moving bodies. Annalen der Physik, 17, 891–921.

Elgin, C. Z. (2014). Fiction as thought experiment. Perspectives on Science, 2, 221-241.

Epstein, L. C. (1995). Thinking physics is gedanken physics. San Francisco, CA: Insight Press.

Fehige, Y., & Stuart, M. T. (2014). On the origins of the philosophy of thought experiments: The Forerun. Perspectives on Science, 22(2), 179-220.

Galili, I. (2009). Thought experiments: Determining their meaning. Science & Education, 18(1), 1–23.

Hadzigeorgiou, Y. (2016). Imaginative science education: The central role of imagination in science education. Basel, Switzerland: Springer.

Klassen, S. (2006). The science thought experiment: How might it be used profitably in the classroom? Interchange, 37(1-2), 77–96.

Kösem, Ş. D., & Özdemir, Ö. F. (2014). The nature and role of thought experiments in solving conceptual physics problems. Science & Education, 23(4), 865–895.

Machery, E. (2011). Thought experiments and philosophical knowledge. Metaphilospohy, 42(3), 191-214.

Merriam, S. B., & Tisdell, E. J. (2016). Qualitative research: a guide to design and implementation. San Francisco, CA: Jossey-Bass.

Meynell, L. (2014). Imagination and insight: A new acount of the content of thought experiments. Synthese, 191, 4149–4168.

Miles, M. B., Huberman, A. M., & Saldaña, J. (2014). Qualitative data analysis: a methods sourcebook, third edition. Los Angeles, CA: Sage publications.

Reiner, M., & Burko, L. M. (2003). On the limitations of thought experiments in physics and the consequences for physics education. Science & Education, 2(4), 365–385.

Schrödinger, E. (1935). Die gegenwärtige situation in der Quantenmechanik (The present situation in quantum mechanics). Naturwissenschaften, 23(48), 807–812.

Sorensen, R. (2016). Thought experiment and imagination. In A. Kind (Ed.), The routledge handbook of philosophy of imagination (pp. 420-436). London, England: Routledge.

Stuart, M. T. (2016). Norton and the logic of thought experiments. Axiomathes, 26, 451–466.

Thagard, P. (2014). Thought experiments considered harmful. Perspectives on Science, 22(2), 288-305.

Velentzas, A., & Halkia, K. (2011). The ‘Heisenberg’s microscope’ as an example of using thought experiments in teaching physics theories to students of the upper secondary school. Research in Science Education, 41, 525–539.

Velentzas, A., & Halkia, K. (2013). The use of thought experiments in teaching physics to upper secondary-level students: two examples from the theory of relativity. International Journal of Science Education, 35(18), 3026–3049.