Garuda - Garba Rujukan Digital

The Effect of STEAM Approach in Physics Learning to Enhance 21st Century Skills : A Literature Review Azizatul Nur Rohmah; Nurita Apridiana Lestari; Hanandita Veda Saphira
Journal of Digitalization in Physics Education Vol. 1 No. 1 April 2025
Publisher : Universitas Negeri Surabaya

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.26740/jdpe.v1i1.38986

Objective: The STEAM approach has an important role in improving 21st-century skills in students so that it can prepare them to face future demands. This study aims to analyze the effect of the STEAM approach in physics learning on improving 21st-century skills. Method: This study is literature research with a qualitative approach that uses national and international journals as data sources. Data were collected through Google Scholar and Scopus, and as many as 20 journal articles related to the STEAM approach in physics learning were published in 2020-2024. The data were analyzed using qualitative descriptive analysis through literature study. Results: Based on the research results, using the STEAM approach has a significant positive impact on various 21st-century skills, including creativity, concept understanding, critical thinking, argumentation skills, and problem-solving. Among these skills, creative thinking skills were the most measured. In addition, the STEAM approach is often integrated with learning models such as STEAM Learning and Project-Based Learning (PjBL). These findings confirm the effectiveness of the STEAM approach in developing comprehensive skills in students. Novelty: This research is expected to provide strategic insights for educators in designing innovative and practical learning, especially by utilizing the STEAM approach to support the needs of 21st-century education.

Multiple Intelligences in Digital Physics Learning for Education for Sustainable Development Hanan Zaki Alhusni; Titin Sunarti; Hanandita Veda Saphira; Riski Ramadani
Journal of Current Studies in SDGs Vol. 1 No. 4 (2025): December
Publisher : Sekolah Tinggi Agama Islam Sabilul Muttaqin Mojokerto

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.63230/jocsis.1.4.101

Objective: This study aims to synthesise research on the application of Multiple Intelligences (MI) in digital physics learning within the framework of Education for Sustainable Development (ESD). The goal is to map trends, highlight opportunities for personalised, sustainability-oriented learning, and identify gaps that hinder the integration of MI and digital technologies to foster sustainability competencies. Method: A Systematic Literature Review (SLR) was conducted following the PRISMA 2020 guidelines. Articles were collected from Google Scholar, Scopus, IEEE Xplore, ERIC, and ScienceDirect, limited to peer-reviewed studies published between 2018 and 2023 in English or Indonesian. Forty eligible studies were analysed thematically and through content analysis. Results: The findings show that MI-based digital learning enhances students' motivation, engagement, conceptual understanding, and academic performance. Interactive simulations, video-based modules, virtual experiments, and AR/VR applications offer personalised learning aligned with students' dominant intelligences. MI also supports ESD competencies such as critical thinking, collaboration, and sustainability awareness, though aspects like environmental literacy, social responsibility, and ethical reasoning remain underexplored. Novelty: This review uniquely links the MI, physics education, and ESD domains, which are rarely integrated in prior studies. It emphasises MI's potential to enhance cognitive outcomes while embedding sustainability values into physics education. A conceptual roadmap is proposed to align MI-based digital physics learning with the Sustainable Development Goals.

Multiple Intelligences in Digital Physics Learning for Education for Sustainable Development Hanan Zaki Alhusni; Titin Sunarti; Hanandita Veda Saphira; Riski Ramadani
Journal of Current Studies in SDGs Vol. 1 No. 4 (2025): December
Publisher : Sekolah Tinggi Agama Islam Sabilul Muttaqin Mojokerto

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.63230/jocsis.1.4.101

Objective: This study aims to synthesise research on the application of Multiple Intelligences (MI) in digital physics learning within the framework of Education for Sustainable Development (ESD). The goal is to map trends, highlight opportunities for personalised, sustainability-oriented learning, and identify gaps that hinder the integration of MI and digital technologies to foster sustainability competencies. Method: A Systematic Literature Review (SLR) was conducted following the PRISMA 2020 guidelines. Articles were collected from Google Scholar, Scopus, IEEE Xplore, ERIC, and ScienceDirect, limited to peer-reviewed studies published between 2018 and 2023 in English or Indonesian. Forty eligible studies were analysed thematically and through content analysis. Results: The findings show that MI-based digital learning enhances students' motivation, engagement, conceptual understanding, and academic performance. Interactive simulations, video-based modules, virtual experiments, and AR/VR applications offer personalised learning aligned with students' dominant intelligences. MI also supports ESD competencies such as critical thinking, collaboration, and sustainability awareness, though aspects like environmental literacy, social responsibility, and ethical reasoning remain underexplored. Novelty: This review uniquely links the MI, physics education, and ESD domains, which are rarely integrated in prior studies. It emphasises MI's potential to enhance cognitive outcomes while embedding sustainability values into physics education. A conceptual roadmap is proposed to align MI-based digital physics learning with the Sustainable Development Goals.

Analyzing Students' Misconceptions Based on Submicroscopic Level Representation in Elements, Compounds, and Mixtures Arum Dwisetyo Arini; Utiya Azizah; Sukarmin; Muhammad Satriawan; Hanandita Veda Saphira
Jurnal Penelitian Pendidikan IPA Vol 11 No 2 (2025): February
Publisher : Postgraduate, University of Mataram

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.29303/jppipa.v11i2.10052

The aim of this study is to analyze misconceptions at the submicroscopic level as well as the causal factors of misconceptions in elemental, compound and mixture materials. This research was conducted using descriptive-quantitative method using three-tier diagnostic test and interview. The research subjects were grade IX with 41 students in a junior high school in Malang. The results of this study indicate that 31.0% of students experience misconceptions in determining the concept of atoms, especially for like and unlike atoms in determining elements, compounds and mixtures, 29.0% in the difference in material changes when viewed from the shape of atoms owned, and 27.0% in changes in the constituent particles of elements, compounds and mixtures. The factors causing this misconception are based on the way of learning, misconceptions from teachers, learning methods, initial abilities, and supporting books. The conclusion of this research is that students experience misconceptions that have an impact on their understanding of concepts, especially for the submicroscopic level. The ability to understand the submicroscopic level which is still low causes the need for efforts in reducing the misconceptions that occur.

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