Effects of small-scale chemistry STEM integrated with local contexts for enhancing grade 11 students’ learning achievement and learning and innovation skills
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Abstract
This study aimed to; a) create the context-based small-scale chemistry STEM (CSSC-STEM) Model; and b) examine the effects of the CSSC-STEM model on students’ learning achievements and learning and innovation skills. The research methodology was Research and Development (R&D). In R1D1, 60 chemistry teachers and 136 students responded to reflect problems and needs about teaching and learning chemistry. In R2D2, 43 and 41 Grade 11 students were in an experiment and control groups, respectively. In R3D3, 40 and 36 students were in the experiment and control groups, respectively. The results showed that the experiment group had higher learning achievement in Rate of Chemical Reactions (t = 7.599, p < 0.05) than the control group. In addition, the experimental group had higher critical problem-solving skills (t = 20.968, p < 0.05) and creative thinking skills (t = 23.168, p < 0.05) than control group. The experiment group also gradually improved communication and teamwork skills throughout the model. The R3D3 results aligned with R2D2 showing the reliability of the CSSC-STEM model.
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References
Acharry, S. The Development of Chemistry Curriculum Via Microscale Experiments for Vocational Learners. Doctor of Education Thesis in Science Education, Srinakharinwirot University, Bangkok, 2009.
Chamrat, S. The Definition of STEM and Key Features of STEM Education Learning Activity. STOU Education Journal. 2017, 10 (2), 13–34. [in Thai].
Chanprasert, S. STEM education and Teaching and Learning in the 21st Century. IPST Magazine. 2014, 42 (186), 3-5. [In Thai].
Chaolumbua, S. Development of STEM Education Curriculum on Sugar Cane for Grade 9 Students. Doctor of Education Thesis, Srinakharinwirot University, Bangkok, 2015. [In Thai].
Chulawattanatol. M. STEM Education Thailand and STEM Ambassadors. Institute for the Promotion of Teaching Science and Technology: IPST Magazine. 2013, 42 (185), 14–18. [In Thai].
Jong, O. Context-based Chemical Education: How to Improve it? Chemical Education International. 2006, 8 (1), 1–7.
Faikhamta, C. Strategies for Teaching Chemistry. Chulalongkorn University Press, 2020. [In Thai].
Gilbert, J. K. On the Nature of “context” in Chemical Education. International Journal of Science Education. 2006, 28 (9), 957–976. https://doi.org/10.1080/09500690600702470
Gonzalez, H. B.; Kuenzi, J. J. Science, Technology, Engineering, and Mathematics (STEM) Education: A Primer; Congressional Research Service, 2012.
Kelly, O.; Finlayson, O. E. “Small-Scale Chemistry in the School Laboratory – Small is Beautiful, Green is more Beautiful” 2022.
Khammamung, A. The Study of Learning Achievement in Chemistry on Chemical Reaction and Critical Thinking for Matthayomsueksa 4 on STEM Education. Rangsit University, Bangkok, 2017.
Ketsrisakda, N.; Noin, J.; Tunreun, K.; Poolprasert, P. Learning Achievement and Science Process Skill of Fifth Grade Students Using STEM Education. In Proceedings of the National Research Conference Northern College, Northern College, 2017; Tak, pp. 272–276.
Khonchaiyapham, P. Development of Activity-Based Learning Conceptual Approach with the STEM Education on the Photosynthesis Issue at the 11th Grade Level to Promote Students' Learning Achievement and their Systems Thinking Abilities. Rajabhat Maha Sarakham University, Maha Sarakham, 2017. [In Thai].
Laohapiboon. P. Science Teaching Approaches; Thai Watthanaphanit, 1999. [In Thai].
Loei Rajabhat University. Training Materials for the Comprehensive Teacher Development Program. Faculty of Science and Technology. Loei Rajabhat University, Loei, 2018. [In Thai].
Lou, S. J.; Shih, R. C.; Diez, C. R.; Tseng, K. H. The impact of problem-based learning strategies on STEM knowledge integration and attitudes: An exploratory study among female Taiwanese senior high school students. International Journal of Technology and Design Education. 2011, 21 (2), 195–215. https://doi.org/10.1007/s10798-010-9114-8
Ministry of Education. The Basic Education Core Curriculum B.E. 2551 (BE. 2560 revised edition (A.D. 2017); The Printing House of Express Transportation Organization of Thailand, 2017. [In Thai].
National Center for STEM Education of Institute for the Promotion of Teaching Science and Technology. Introduction to STEM Education. STEM Education Thailand, IPST, Bangkok, 2015.
National Research Council. A Framework For K-12 Science Education: Practices, Crosscutting Concept, and Core Ideas. Committee on New Science Education Standards, Board on Science Education, Division of Behavioral and Social Science and Education National Academy Press, 2012.
Office of the Education Council. National Education Act B.E. 2542 (1999) and Amendments (Second National Education Act B.E. 2545 (2002)); Office of the Education Council, Bangkok, 2002. [In Thai].
Pudcha, W. A Comparative Study of Learning Achievement on Trigonometry Ratios Between the Use of Stem Education and IPST Method for Mathayom Suksa 5 Wathuaichorakhe Wittayakhom School. Master of Science Thesis in Mathematics Study, Silpakorn University, Nakhon Pathom, 2016.
Passakchai, P.; Kuno, M. The Development of Computer-Assisted Instruction on the Topic of Chemical Reaction For Matthayomsuksa 2 Students. Veridian E-Journal, Silpakorn University. 2015, 8 (2), 483–492. [In Thai].
Penratanahiran, R.; Thongkham, K. A Survey of Soft Skills Needed in the 21st Century Workplace. Rajabhat Rambhai Barni Research Journal. 2011, 15 (1), 59–69. [In Thai].
Penrattanahiran, R. An Analysis of Problems and Guidelines for Enhance 4Cs Skills of Primary School Students under Chiang Mai Primary Educational Service Area Office 3. Journal of MCU Peace Studies. 2021, 10 (2), 675–692. [In Thai].
Poonruang, A. A Development of Learning Achievement and Ability in Problem-Solving in Science through STEM Education Approach in Enzyme. Master of Education Thesis in Biology, Srinakharinwirot University, Bangkok (2016). [ In Thai].
Prakun, C. Integrated Design of Reading, Analytical Thinking, and Writing Instruction. 2nd Edition. Chulalongkorn University Press (Cuprint), 2009. [In Thai].
Saengpromsri. P. Comparisons of Learning Achievement, Integrated Science Process Skills, and Attitude Towards Chemistry Learning for Matthayomsueksa 5 Students between STEM education and Conventional Method. Mahasarakham University, Mahasarakham 2015. [In Thai].
Samahito, C. Training Material for Practical Training, Integrating Science, Technology, Engineering, and Mathematics (STEM) Activities for Early Childhood Education. Pre-school Education Association of Thailand Under the Royal Patronoge of Her Royal Highness Maha Chakri Sirindhorn "P.E.A.T", 2014. [In Thai].
Seneewong, S. STEM Education through Origami Frog. IPST Magazine. 2013, 42 (185), 10–13. [In Thai].
Shi-Jer Lou; Ru-Chu Shih; C. Ray Diez; Kuo-Hung Tseng. The Impact of Problem-Based Learning Strategies on STEM Knowledge Integration and Attitudes: An Exploratory Study among Female Taiwanese Senior High School Students. Int. J. Technol. Des. Educ. 2011, 10 (1007), 195–215. https://doi.org/10.1007/s10798-010-9114-8
Singh, M. M.; Szanfran, Z.; Pike, R. M. Microscale Chemistry and Green Chemistry: Complementary Pedagogies. J. Chem. Educ. 1999, 12 (76), 1684–1686. https://doi.org/10.1021/ed076p1684
Siriphatrachai. P. STEM Education and 21st Century Skills Development. Executive Journal. 2013, 33 (2), 49–56. [In Thai].
Sombatsri; Kantadong, P.; Chankaew, C.; Asavasukhee, A. Green Chemistry. Journal of Science and Technology. Ubon Ratchathani University. 2016, 18 (3), 1–15. [In Thai]. https://doi.org/10.30574/ijsra.2023.8.2.0225
Tamuang, S.; Wuttisela, K.; Supasorn, S. Development of 11th Grade Students’ Conceptual Understanding of Chemical Reaction Rate by using Inquiry Experiments. CMU Journal of Education. 2017, 1 (2), 1–15. [In Thai].
Thongchai, A. STEM Education and Development of Education in Science, Technology, engineering and Mathematics in USA. Association of Science, Mathematics and technology Teachers of Thailand. 2013, 19 (1), 15–18.
Tontayanon, S. Green Chemistry: Theory and Practice. Bangkok: STC Media and Maketing, 2011.
Wicheansang, K.; Mophan, N.; Lateh, A. Effect of STEM Education on Chemistry Achievement, Problem-Solving Ability and Instructional Satisfaction of Grade 12 Students. Prince of Songkhla University Pattani Campus. 2018, 29 (3), 148–158. [In Thai].
Wood, C. G. Microchemistry. J. Chem. Educ. 1990, 67 (7), 596–597. https://doi.org/10.1021/ed067p596
Wooster, M. Microscale Chemistry. Educ. Chem. 2007, 44 (2), 45–47.