弗兰克-赫兹实验的不同数据处理方法对比及第一性原理模拟

doi:10.14139/i.cnki.cn22-1228.2024.06.016

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摘要

弗兰克-赫兹实验对于验证电子能量的量子化有着重要的意义,是近代物理实验中的经典。然而,实验结果一般受实验条件和数据处理方法的限制。本文利用Ｍａｔｌａｂ软件对测量的八组数据进行分段的线性插值、三次Ｈｅｒｍｉｔｅ插值及三次样条插值并绘制曲线图,计算单原子气体氩的第一激发电位,比较发现三次样条插值拟合的曲线更加平滑且结果的一致性更好。同时,通过以量子力学为基础的第一性原理计算得到了气体氩的第一激发电位,并将其与实验结果进行了对比分析,发现相比Ｐｅｒｄｅｗ-Ｂｕｒｋｅ-Ｅｒｎｚｅｒｈｏｆ(ＰＢＥ)泛函,使用Ｈｅｙｄ-Ｓｃｕｓｅｒｉａ-Ｅｒｎｚｅｒｈｏｆ(ＨＳＥ０６)泛函计算的第一激发电位与实验值有更好的吻合,而自旋轨道耦合的引入会导致能级的劈裂,但不会明显改变激发电位。

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	刘律廷
	牛相宏
	李永涛

关键词: 弗兰克-赫兹实验大学物理实验插值方法第一性原理

Abstract:

The Frank-Hertz experiment is important for verifying the quantization of electron energy and is aclassie in recent physics experiments, However, the experimental results are generally limited by the experimental conditions and data processing methods. In this paper, Matlab soltware is used to calculate the first excitation potential of monatomie gas argon by segmented linear interpolation , three times Hermite inte rpolation and three times spline interpolation and ploting the curve of eight sets of measured data, and it is found that the curve fitted by three times spline interpolation is smoother and the consisency of the results is belter. Meanwhile ,the first exeitation potential of the gas argon is obtained by the quantum mechanics-based first nature prineiple caleulation, and compared with the experimental results, it is found that compared with the Perdew-Burke-Erzerhof( PBE ) generalized funetion, the first excitation potential calculated by using theHeyd-Seuseria-Emzerhof( HSE06 ) generalized function has a better agreement with the experimental value ,and the introduction of spin-orbit coupling leads to the cleavage of the energy level but does not change theexeitation potential significantly.

Key words: Franck-lertz experiment university physics experiments interpolation method first principles

出版日期: 2024-12-25 发布日期: 2024-12-25 整期出版日期: 2024-12-25

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引用本文:

刘律廷, 牛相宏 , 李永涛. 弗兰克-赫兹实验的不同数据处理方法对比及第一性原理模拟 [J]. 大学物理实验, 2024, 37(6): 87-91.
LIU Lvting, NlU Xianghong, LI Yongtao. Comparison of Different Data Processing Methods and First Principle Simulations of Frank-Hertz Experiments . Physical Experiment of College, 2024, 37(6): 87-91.

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https://dawushiyan.jlict.edu.cn/CN/10.14139/i.cnki.cn22-1228.2024.06.016 或 https://dawushiyan.jlict.edu.cn/CN/Y2024/V37/I6/87

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