PELATIHAN PEMBELAJARAN CODING DALAM MERANCANG APLIKASI KALKULATOR SEDERHANA
DOI:
https://doi.org/10.53067/ijecsed.v5i3.238Keywords:
Coding, Stoichiometry, Calculator Application, Mathematics, Deep LearningAbstract
A thorough understanding of stoichiometry is crucial for success in chemistry and related fields, such as biology, chemical engineering, and materials science. Without a solid understanding, students will struggle to interpret chemical equations, calculate the quantities of substances involved in reactions, and predict the outcome of reactions. However, learning stoichiometry often presents a challenge for students. Many students tend to be "algorithmic problem solvers" rather than "conceptual thinkers" in chemistry. To address the challenges of learning stoichiometry, current technological advances have begun to offer significant potential for enhancing student understanding. Technological advancements appear to be a lifeline when students encounter difficulties. One such application is the Simple Stoichiometry Calculator App. Stoichiometry calculator apps can help students visualize abstract concepts, solve problems step-by-step, and receive instant feedback. In addition to existing applications, learning through coding can also be an engaging and interactive solution for students. This is because coding not only requires technical skills but also tools for developing logical thinking, problem-solving, and creativity. The integration of coding and chemistry, particularly in the development of a simple stoichiometry calculator application, offers an innovative approach to enhancing classroom learning. In light of the aforementioned issues, a well-designed Simple Stoichiometry Calculator Application is expected to address this need. Therefore, this community service program focused on coding for chemistry has significant potential to improve the quality of chemistry education in schools at the junior high school (SMP) level.
Downloads
References
Adrezo, M., Yulnelly, Intan, H. I., (2023). Pengenalan Coding dalam rangka peningkatan Literasi Digital Bagi Siswa M. I. Jami’atul Khair Ciledug Tanggerang. Kumawula: Jurnal Pengabdian Kepada Masyarakat, Vol 6 No 3 706-713
Bers, M. U. (2018). Coding as a playground: Programming and computational thinking in the early childhood classroom. Routledge.
Brown, T. L., LeMay, H. E., Bursten, B. E., Murphy, C. J., & Woodward, P. M. (2018). Chemistry: The central science (14th ed.). Pearson Education.
Blikstein, P. (2013). Digital fabrication and ‘making’ in education: The democratization of invention. In J. Walter-Herrmann & C. Büching (Eds.), FabLabs: Of machines, makers and inventors (pp. 203-222). Transcript Publishers.
Chandrasegaran, A. L., Treagust, D. F., Waldrip, B. G., & Chandrasegaran, A. (2009). Students’ dilemmas in transferring learning from physics to chemistry when learning stoichiometry. Instructional Science, 37(4), 403-425.
Effendi, A., & Suryanto, E. (2015). Pengembangan media pembelajaran interaktif berbasis komputer pada materi stoikiometri untuk meningkatkan pemahaman konsep siswa. Jurnal Pendidikan Sains, 3(2), 101-108. (Jurnal Nasional)
Hakim, A., & Widodo, W. (2016). Pengembangan media pembelajaran interaktif berbasis android pada materi stoikiometri untuk meningkatkan hasil belajar siswa. Jurnal Pendidikan Kimia, 8(2), 123-130. (Jurnal Nasional)
Holme, T. A., Bretz, S. L., Cooper, M. M., & Towns, M. H. (2015). Research on the role of visualization in chemistry education. Journal of Chemical Education, 92(10), 1607-1611.
Kalelioglu, F. (2015). A framework for computational thinking based on systems thinking. Journal of Baltic Science Education, 14(6), 766.
Kementerian Pendidikan, Kebudayaan, Riset, dan Teknologi. (2022). Permendikbudristek Nomor 56 Tahun 2022 tentang Kurikulum Merdeka. Jakarta: Kemdikbudristek.
Krajcik, J. S., & Shin, N. (2014). Project-based learning. In K. Sawyer (Ed.), The Cambridge handbook of the learning sciences (2nd ed., pp. 275-297). Cambridge University Press.
Nurbaeti, N., & Redjeki, S. (2019). Pengembangan media pembelajaran interaktif berbasis android pada materi stoikiometri untuk meningkatkan keterampilan berpikir kritis siswa. Jurnal Penelitian Pendidikan IPA, 5(1), 1-7. (Jurnal Nasional)
Puspaningtyas, N., Rusdiana, D., & Siahaan, P. (2016). Pengembangan multimedia interaktif untuk pembelajaran stoikiometri berbasis android.Jurnal Inovasi Pendidikan Kimia, 10(1), 1711-1720. (Jurnal Nasional)
Rahayu, S., & Widodo, W. (2017). Pengembangan media pembelajaran interaktif berbasis android pada materi stoikiometri untuk meningkatkan motivasi belajar siswa. Jurnal Inovasi dan Pembelajaran Fisika, 4(2), 109-116.
Resnick, M., Maloney, J., Monroy-Hernández, A., Rusk, N., Eastmond, E., Brennan, K., ... & Kafai, Y. B. (2009). Scratch: Programming for all. Communications of the ACM, 52(11), 60-67.
Supardi, Z. A. I., & Widodo, W. (2018). Pengembangan media pembelajaran interaktif berbasis android pada materi stoikiometri untuk meningkatkan hasil belajar siswa. Jurnal Pendidikan: Teori, Penelitian, dan Pengembangan, 3(11), 1505-1512.
Widodo, C. S., & Kadarwati, S. (2013). Pengembangan perangkat lunak pembelajaran kimia berbasis multimedia interaktif pada materi stoikiometri. Jurnal Pendidikan Kimia (JPK), 2(1), 1-10.
Williamson, V. M. (2019). Teaching chemistry with technology: Best practices. Journal of Chemical Education, 96(1), 1-3.
Yadav, A., Mayfield, C., Zhou, N., Hambrusch, S., & Korb, J. T. (2011). Computational thinking in elementary and secondary teacher education. ACM Transactions on Computing Education (TOCE), 11(3), 1-16.
Zulfikar, M., & Widodo, W. (2019). Pengembangan media pembelajaran interaktif berbasis android pada materi stoikiometri untuk meningkatkan keterampilan berpikir kritis siswa. Jurnal Penelitian Pendidikan IPA, 5(1), 1-7. (Jurnal Nasional)
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2025 Jane Elnovreny, Siti Fatimah Sihotang, Zuhri, Regina Liwanda, Juwita Adellia
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
