1. Theoretical Explanation Basic concepts and physical significance of blackbody radiation. Planck’s law of blackbody radiation and its historical background. The importance of blackbody radiation in modern physics and technological applications. 2. Instrument Introduction Components and functions of the blackbody radiation experimental apparatus. Operational methods and safety precautions. Measurement and recording of experimental data. 3. Experimental Demonstration Simulation of blackbody radiation spectrum changes at different temperatures. Measurement and analysis of the energy distribution and peak wavelength variations. Validation of Stefan-Boltzmann law and Wien’s displacement law through experimental results. 4. Teaching Discussion and Application Extension Discussion of the consistency between experimental results and blackbody radiation theory. Exploration of the application of blackbody radiation concepts in astronomy, optics, and thermal engineering. 5. Target Audience This activity is designed for university physics students and researchers or scholars interested in quantum physics and thermal radiation phenomena. 6. Expected Outcomes Through this activity, participants will: Gain a deeper understanding of the theoretical background and experimental methods of blackbody radiation. Acquire practical skills in operating blackbody radiation experimental instruments. Develop the ability to apply blackbody radiation theory to analyze real-world problems.

Implemented by College of Science
Date: 2024/12/24