Trends in STEM-based physics education research (2016-2025): A systematic literature review

Rahmania Amanah  Putri; Heru Kuswanto; Rahmi Rahmi; I'liyatunnisa' I'liyatunnisa'; Meza Saputri; Muh. Syahrul  Padli; Tugirin Tugirin; Masak Masak; Muhammad Najih  Hamdi; Nurul Aziza

doi:10.20897/ejsteme/18497

Review Article

2026, 11(1), Article No: 28

Trends in STEM-based physics education research (2016-2025): A systematic literature review

Rahmania Amanah Putri ¹ ^* , Heru Kuswanto ¹, Rahmi Rahmi ¹, I'liyatunnisa' I'liyatunnisa' ², Meza Saputri ², Muh. Syahrul Padli ¹, Tugirin Tugirin ¹, Masak Masak ¹, Muhammad Najih Hamdi ¹, Nurul Aziza ¹

¹ Universitas Negeri Yogyakarta, Yogyakarta, INDONESIA ² Universitas Airlangga, Surabaya, INDONESIA
^* Corresponding Author

https://doi.org/10.20897/ejsteme/18497

Published in Volume 11 Issue 1: 03 May 2026

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Abstract

The integration of STEM (Science, Technology, Engineering, and Mathematics) in physics education is gaining increasing global attention due to its role in developing 21st-century competencies such as critical thinking, creativity, and technological literacy. This study presents a systematic literature review (SLR) of STEM-based physics education research published in Scopus-indexed journals between 2016 and 2025. Following the PRISMA protocol, 57 articles meeting the criteria were analysed through thematic and descriptive synthesis. The results of the analysis indicate a significant increase in research activity after 2018, with a peak in publications occurring in 2023. Indonesia, Malaysia, and the United States emerged as the main contributors. This review also revealed that Project-Based Learning (PjBL) and Problem-Based Learning (PBL) are the most widely used pedagogical models, whilst technology-based strategies such as Arduino-based digital learning and the flipped classroom appear to be growing in prominence. Although STEM research is growing globally, there remains a gap in theoretical coherence, namely that most studies have not elucidated how the integration of STEM components (S, T, E, M) is applied in research. Furthermore, no studies have examined teachers’ digital readiness when implementing STEM in physics education, and there are limitations in studies across certain educational levels. Future research is recommended to use a longitudinal and mixed-methods approach to examine how STEM integration can enhance scientific literacy and higher-order thinking skills in physics education

Figure 1. PRISMA research flowchart

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In-text citation: (Putri et al., 2026)
Reference: Putri, R. A., Kuswanto, H., Rahmi, R., I'liyatunnisa', I., Saputri, M., Padli, M. S., Tugirin, T., Masak, M., Hamdi, M. N., & Aziza, N. (2026). Trends in STEM-based physics education research (2016-2025): A systematic literature review. European Journal of STEM Education, 11(1), Article 28. https://doi.org/10.20897/ejsteme/18497

AMA 10th edition

In-text citation: (1), (2), (3), etc.
Reference: Putri RA, Kuswanto H, Rahmi R, et al. Trends in STEM-based physics education research (2016-2025): A systematic literature review. European Journal of STEM Education. 2026;11(1), 28. https://doi.org/10.20897/ejsteme/18497

Chicago

In-text citation: (Putri et al., 2026)
Reference: Putri, Rahmania Amanah, Heru Kuswanto, Rahmi Rahmi, I'liyatunnisa' I'liyatunnisa', Meza Saputri, Muh. Syahrul Padli, Tugirin Tugirin, Masak Masak, Muhammad Najih Hamdi, and Nurul Aziza. "Trends in STEM-based physics education research (2016-2025): A systematic literature review". European Journal of STEM Education 2026 11 no. 1 (2026): 28. https://doi.org/10.20897/ejsteme/18497

Harvard

In-text citation: (Putri et al., 2026)
Reference: Putri, R. A., Kuswanto, H., Rahmi, R., I'liyatunnisa', I., Saputri, M., Padli, M. S., . . . Aziza, N. (2026). Trends in STEM-based physics education research (2016-2025): A systematic literature review. European Journal of STEM Education, 11(1), 28. https://doi.org/10.20897/ejsteme/18497

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Reference: Putri, Rahmania Amanah et al. "Trends in STEM-based physics education research (2016-2025): A systematic literature review". European Journal of STEM Education, vol. 11, no. 1, 2026, 28. https://doi.org/10.20897/ejsteme/18497

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In-text citation: (1), (2), (3), etc.
Reference: Putri RA, Kuswanto H, Rahmi R, I'liyatunnisa' I, Saputri M, Padli MS, et al. Trends in STEM-based physics education research (2016-2025): A systematic literature review. European Journal of STEM Education. 2026;11(1):28. https://doi.org/10.20897/ejsteme/18497

Keywords

STEM, physics education, systematic literature review, technology integration, 21st-century skills

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