Enhancing Conceptual Understanding and Retention in Thermodynamics through Haptic-Enhanced Immersive Simulations: A Quasi-Experimental Study
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| Title: | Enhancing Conceptual Understanding and Retention in Thermodynamics through Haptic-Enhanced Immersive Simulations: A Quasi-Experimental Study |
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| Language: | English |
| Authors: | John Paul D. Purigay |
| Source: | Research in Learning Technology. 2025 33. |
| Availability: | Association for Learning Technology. Gipsy Lane, Headington, Oxford OX3 0BO, UK. e-mail: enquiries@alt.ac.uk; Web site: https://journal.alt.ac.uk |
| Peer Reviewed: | Y |
| Page Count: | 14 |
| Publication Date: | 2025 |
| Document Type: | Journal Articles Reports - Research |
| Education Level: | Secondary Education Postsecondary Education |
| Descriptors: | Science Education, Thermodynamics, Teaching Methods, Visual Stimuli, Tactual Perception, Instructional Effectiveness, Feedback (Response), Secondary School Students, Science Achievement, Postsecondary Education, STEM Education, Foreign Countries, Difficulty Level, Cognitive Processes |
| Geographic Terms: | Philippines |
| ISSN: | 2156-7069 2156-7077 |
| Abstract: | Immersive technologies are increasingly used in science education, yet the role of embodied interaction -- particularly haptic feedback -- in promoting conceptual understanding remains underexplored. This study investigated the effectiveness of Haptic + Visual Immersive Simulations (H+VISs) compared to Visual-only Immersive Simulations (VOISs) in teaching thermodynamics. A quasi-experimental design was employed with 130 secondary students, who completed pre-, immediate post-, and delayed post-tests using a validated Thermodynamics Concept Test. Results showed that the HVIS group significantly outperformed the VIS group in both post-tests, indicating improved learning gains and retention. The HVIS group also scored higher on the Embodied Thermodynamics Scale and reported lower cognitive load, as measured by the Paas scale. Repeated measures analysis of variance revealed significant main effects for time and group, as well as a significant interaction, favoring the HVIS condition. National Aeronautics and Space Administration (NASA-TLX) ratings indicated that the HVIS group experienced higher perceived performance and lower effort and frustration. Path analysis further revealed that embodied learning partially mediated the effect of instructional modality on retention. These findings support the integration of haptic feedback in immersive Science and Technology, Engineering and Mathematics (STEM) instruction, emphasizing the role of multisensory engagement in fostering deeper learning and reducing cognitive effort in abstract domains such as thermodynamics. |
| Abstractor: | As Provided |
| Entry Date: | 2026 |
| Accession Number: | EJ1498424 |
| Database: | ERIC |
| Abstract: | Immersive technologies are increasingly used in science education, yet the role of embodied interaction -- particularly haptic feedback -- in promoting conceptual understanding remains underexplored. This study investigated the effectiveness of Haptic + Visual Immersive Simulations (H+VISs) compared to Visual-only Immersive Simulations (VOISs) in teaching thermodynamics. A quasi-experimental design was employed with 130 secondary students, who completed pre-, immediate post-, and delayed post-tests using a validated Thermodynamics Concept Test. Results showed that the HVIS group significantly outperformed the VIS group in both post-tests, indicating improved learning gains and retention. The HVIS group also scored higher on the Embodied Thermodynamics Scale and reported lower cognitive load, as measured by the Paas scale. Repeated measures analysis of variance revealed significant main effects for time and group, as well as a significant interaction, favoring the HVIS condition. National Aeronautics and Space Administration (NASA-TLX) ratings indicated that the HVIS group experienced higher perceived performance and lower effort and frustration. Path analysis further revealed that embodied learning partially mediated the effect of instructional modality on retention. These findings support the integration of haptic feedback in immersive Science and Technology, Engineering and Mathematics (STEM) instruction, emphasizing the role of multisensory engagement in fostering deeper learning and reducing cognitive effort in abstract domains such as thermodynamics. |
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| ISSN: | 2156-7069 2156-7077 |