Research on the Teaching Reform of High School Physics Curriculum under the Top-Talent Training Model
Abstract
Against the backdrop of China’s strong emphasis on cultivating top innovative talents, the high school physics curriculum, as a core component of scientific education, bears the crucial mission of fostering students’ scientific thinking, creativity, and practical ability. However, current physics teaching still faces issues such as fragmented content systems, weak experimental and inquiry components, and single evaluation methods, which fail to align with the objectives of top-talent cultivation [1]. Guided by the top-talent training model, this study systematically explores reform paths for the high school physics curriculum in terms of educational philosophy, course content, teaching methods, and evaluation mechanisms. The research proposes reconstructing the curriculum system around the main thread of “core concepts–inquiry practice–innovative application,” strengthening interdisciplinary integration and the inclusion of frontier modern physics topics. In teaching methodology, it advocates for a shift toward problem-driven, project-based, and self-directed learning models, leveraging information and intelligent technologies to enhance classroom effectiveness. In evaluation, it suggests building a comprehensive system centered on formative assessment and innovation capability evaluation. Based on the reform practice of a key high school’s top-talent experimental class, the findings show significant improvements in students’ scientific inquiry skills and creative thinking, as well as optimization of teaching philosophy and classroom ecology. The results provide theoretical and practical references for high school physics curriculum reform in the new era and offer insights into the construction of top-talent cultivation systems.
References
Ye D, Tan Y, Wang S, 2024, Reform and Practice of Cultivation Mode of Top Talents in Product Design Specialty under the Background of Industry-Teaching Integration. Advances in Humanities and Modern Education Research, 1(1): 98–104.
Shi D, Liu W, Wang Y, 2023, Has China’s Young Thousand Talents Program Been Successful in Recruiting and Nurturing Top-Caliber Scientists? Science, 379(6627): 62–65.
Luo J, 2025, An Inquiry Beneath the Twin Peaks: Examining University Physics Education in Mainland China from the Perspectives of Feynman’s Intuition and Landau’s Rigor. Journal of Engineering Systems and Applications, 1: 1–7.
Yao W, Qian S, Xie W, 2025, Exploring the Effectiveness of Micro-Credentials in Artificial Intelligence Teaching and Learning: An Empirical Study Based on AI+ X Program in China. Cogent Education, 12(1): 2536528.
Temel Y, Coskun B, 2024, A Review on Artificial Intelligence Applications in Education in Some Countries and Türkiye. International Technology and Education Journal, 8(1): 9–23.
Yamada A, 2023, STEM Field Demand and Educational Reform in Asia-Pacific Countries, The Oxford Handbook of Higher Education in the Asia-Pacific Region, 189–209.
Chong G, et al., 2024, Research on the Sustainable Cultivation Mode of Innovative Talents in Developing Countries. Journal of Industrial Integration and Management, 9(4): 555–569.
Wang S, Huang X, 2024, A Review on Higher Education of Fire Safety in China. Fire Technology, 60(2): 757–816.
Smith V, Husband G, 2024, Guest Editorial: Teacher Recruitment and Retention Challenges in the Further Education and Skills Sector: Lessons and Solutions from International Perspectives. Education+ Training, 66(5): 465–476.
Alda RC, Boholano HB, De Leon-Abao E, 2025, Career Progression of Graduates in Diploma for Professional Education. Journal of Education and Learning (EduLearn), 19(1): 1–13.
