The Influence of the Deep Learning Approach on Students' Physics Learning Outcomes

Dina Suardin; Haeruddin Haeruddin; Nurul Kami Sani; Muhammad Jarnawi; Muhammad Zaky; Andi Ulfah Khuzaimah

doi:10.30605/jsgp.8.3.2025.6833

Authors

Dina Suardin Universitas Tadulako
Haeruddin Haeruddin Universitas Tadulako
Nurul Kami Sani Universitas Tadulako
Muhammad Jarnawi Universitas Tadulako
Muhammad Zaky Universitas Tadulako
Andi Ulfah Khuzaimah Universitas Tadulako

DOI:

https://doi.org/10.30605/jsgp.8.3.2025.6833

Keywords:

Deep Learning Approach, Learning Outcomes, Physics

Abstract

This study aims to analyze the effect of a Deep Learning approach combined with Problem-Based Learning (PBL) on students' physics learning outcomes regarding the topic of the First Law of Thermodynamics. The urgency of this research is based on students' low understanding of the concepts of energy, heat, and work, as well as the high rate of misconceptions that impact physics learning achievement. The research method used a quantitative approach with a quasi-experimental design of the Nonequivalent Control Group Design type. The sample was determined through purposive sampling, consisting of 31 students from class XI H as the experimental group and 28 students from class XI I as the control group at MAN 2 Palu. The research instruments were a learning outcome test (pretest-posttest) and an observation sheet. Data analysis included normality tests, homogeneity tests, hypothesis testing with the Mann-Whitney U Test, and N-Gain calculation. The results showed a significant difference between the experimental and control groups (p = 0.000 < 0.05). The average N-Gain score for the experimental group reached 87.70 (high category), while the control group only reached 69.08 (medium category). Observations of the learning implementation also obtained an average score of 93% (very good category). It can be concluded that the application of the PBL-based Deep Learning approach is effective in improving the understanding of physics concepts, specifically on the material of the First Law of Thermodynamics. This approach is able to foster learning that is more mindful, meaningful, and joyful, making it relevant for supporting the achievement of 21st-century competencies.

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References

Andriadi, F. M., Alatas, F., & Solehat, D. (2024, July). Studi literatur miskonsepsi pembelajaran hukum I termodinamika: identifikasi dan solusi. In Prosiding Seminar Nasional Fakultas Ilmu Tarbiyah dan Keguruan UIN Syarif Hidayatullah Jakarta (Vol. 1, No. 1, pp. 170-180).

Aprodita, F., Haryanto, Z., & Hakim, A. (2023). Analisis Buku Teks Pelajaran Fisika SMA/MA Kelas X Kurikulum 2013 Berdasarkan Pendekatan Saintifik. Jurnal Literasi Pendidikan Fisika (JLPF), 4(2), 110-118.

Ardianti, Y., & Amalia, N. (2022). Kurikulum merdeka: Pemaknaan merdeka dalam perencanaan pembelajaran di sekolah dasar. Jurnal Penelitian Dan Pengembangan Pendidikan, 6(3), 399-407. http://dx.doi.org/10.23887/jppp.v6i3.55749

Asmi, Y. K., & Wijayanto, Z. (2022). Pengaruh pendekatan deep learning dan media interaktif berbasis platform digital canva terhadap hasil belajar pengukuran luas di sekolah dasar. Didaktika Dwija Indria, 13(2). https://doi.org/10.20961/ddi.v13i2.101285

Barokah, A., Sugianto, S., & Astuti, B. (2021). Analisis Perencanaan Pengembangan Instrumen Evaluasi Berbasis Higher Order Thinking Skills (Hots) Materi Hukum Termodinamika. Phenomenon: Jurnal Pendidikan MIPA, 11(1), 75-86. https://doi.org/10.21580/phen.2021.11.1.7303

Brown, B., & Singh, C. (2021). Student understanding of the first law and second law of thermodynamics. European Journal of Physics, 42(6), 065702. https://doi.org/10.1088/1361-6404/ac18b4

Feriyanto, F., & Anjariyah, D. (2024). Deep learning approach through meaningful, mindful, and joyful learning: A library research. Electronic Journal of Education, Social Economics and Technology, 5(2), 208-212. https://doi.org/10.33122/ejeset.v5i2.321

Haeruddin, H., Kamaluddin, K., Kade, A., & Pabianan, A. R. (2022). Analysis of attitudes and approaches to problem solving: gender differences and education levels. Radiasi: Jurnal Berkala Pendidikan Fisika, 15(1), 12-21. https://doi.org/10.37729/radiasi.v15i1.1816

Haspen, C. D., & Syafriani, S. (2022). Praktikalitas dan Efektifitas Emodul Fisika Berbasis inkuiri Terbimbing Terintegrasi Etnosains Untuk Meningkatkan Kemampuan Berpikir Kreatif Peserta Didik (Doctoral dissertation, Universitas Negeri Padang).

Hidayat, T., & Kosasih, A. (2019). Analisis peraturan menteri pendidikan dan kebudayaan republik indonesia nomor 22 tahun 2016 tentang standar proses pendidikan dasar dan menengah serta implikasinya dalam pembelajaran pai di sekolah. Muróbbî: Jurnal Ilmu Pendidikan, 3(1), 45-69. https://doi.org/10.52431/murobbi.v3i1.172

Kadarismanto, K., & Sari, K. P. (2025). Konsep Deep Learning sebagai Pilar dalam Strategi Pendidikan Berkualitas. Pedagogia: Jurnal Keguruan dan Kependidikan, 2(1), 594139.

Marton, F., & Säljö, R. (1976). On qualitative differences in learning: I—Outcome and process. British journal of educational psychology, 46(1), 4-11. https://doi.org/10.1111/j.2044-8279.1976.tb02980.x

OECCD. (2023). PISA 2022 Results (Volume I & II) – Country Notes: Indonesia.

Popovic, C. (2013). Teaching for quality learning at university.(2nd Edn.).

Putriyanti, S. dan U. W. (2021). Pengaruh Model Pembelajaran Problem Based Learning Terhadap Hasil Belajar Fisika Siswa Kelas Xi Ipa Sma Negeri 4 Halmahera …. 1(November), 20–26.

Qolby, B. S. (2014). Uji mann whitney dalam statistika non parametrik perbedaan tingkat penggunaan kendaraan umum dengan kendaraan pribadi. Jurnal PkM Pengabdian Kepada Masyarakat, 2(8), 15.

Sani, N. K., & Darmadi, I. W. (2025). The Impact of Synectics Learning Model Implementation with Mind Mapping Assignments on Reducing Misconceptions and Enhancing Students' Cognitive Learning Outcomes. Jurnal Penelitian Pendidikan IPA, 11(1), 835-841. https://doi.org/10.29303/jppipa.v11i1.9274

Sasmita, P. R., Sahida, D., & Mawati, R. (2022). Penerapan Model Pembelajaran Kontekstual Terhadap Hasil Belajar Fisika. Jurnal Ilmiah Pendidik Indonesia, 1(2), 129-132. https://doi.org/10.56916/jipi.v1i2.222

Smith, K., Maynard, N., Berry, A., Stephenson, T., Spiteri, T., Corrigan, D., ... & Smith, T. (2022). Principles of problem-based learning (PBL) in STEM education: Using expert wisdom and research to frame educational practice. Education Sciences, 12(10), 728. https://doi.org/10.3390/educsci13100728

Sudarta, I. K. (2022). Meningkatkan prestasi belajar fisika melalui penerapan model pembelajaran contextual teaching and learning (CTL) dengan mind mapping. Indonesian Journal of Educational Development (IJED), 2(4), 599-608. https://doi.org/10.5281/zenodo.6203651

Sugiyono. (2019). Metodologi Penelitian Kuantitatif, Kualitatif dan R & D.

Sunardi, R. (2021). Meningkatkan Hasil Belajar Siswa Kelas XI IPA Tahun Pelajaran 2019/2020 Pada Materi Hukum Termodinamika dengan Model Pembelajaran Inkuiri di SMAN 14 Tebo. Jurnal Literasiologi, 5(2). https://doi.org/10.47783/literasiologi.v5i2.218

Sutikno, T., & Wibowo, A. (2020). Identifikasi Miskonsepsi Siswa pada Materi Fluida Statik. Jurnal Pendidikan Fisika Dan Teknologi, 6(1), 18–25. https://doi.org/10.11594/timeinphys.2025.v3i1p8-14

Wahyudi, D. A. (2025). Pengaruh Pembelajaran Deep Learning terhadap Kemampuan Penalaran Matematis dan Kepercayaan Diri Siswa SMA Dharma Pancasila Medan. Jurnal Inovasi Pendidikan Pedagogi, 1(1), 9-17.

Wijaya, A. A., Haryati, T., & Wuryandini, E. (2025). Implementasi pendekatan deep learning dalam peningkatan kualitas pembelajaran di SDN 1 Wulung, Randublatung, Blora. Indonesian Research Journal on Education, 5(1), 451-457. https://doi.org/10.31004/irje.v5i1.1950

Winje, Ø., & Løndal, K. (2020). Bringing deep learning to the surface: A systematic mapping review of 48 years of research in primary and secondary education. Nordic Journal of Comparative and International Education, 4(2), 25–41. https://doi.org/10.7577/njcie.3798