Table of Content

09 May 2025 Volume 44 Issue 3

  

Achievements and style of Fermi in supervising and instructing students

ZHAO Yumin

College Physics. 2025, 44(3):  1.  doi:10.16854/j.cnki.1000-0712.240290

Abstract ( 336 )   PDF (510KB) ( 238 )  

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We summarize the great achievements of Enrico Fermi in his training and instructing students and young research fellows,  with an overview of the features that Fermi educated his students, assistants, and young research fellows. Fermi encouraged all the time those students and young fellows to go ahead, and none of Fermi’s students simply followed Fermi’s old works. Fermi educated students according to individual ability and specialty, found the shining and unique points of each soul, and instructed each to shine in its special and natural way. Fermi’s above style in education provides us with a nice example in training young generations.




Calculation of degenerate perturbation for a helium atom

HUANG Yongyi

College Physics. 2025, 44(3):  3.  doi:10.16854/j.cnki.1000-0712.240265

Abstract ( 300 )   PDF (610KB) ( 245 )  

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We construct the zeroth approximate wavefunctions using Slaters determinants, calculate energy levels and their wavefunctions of a Helium atom in exited states, and discuss its ground energy level and ground wavefunction.



Study on the wave packet scattering in defective Dirac comb

DENG Zhijiao, CHENG Hang, SHEN Yong, SHI Shuai, CHEN Pingxing

College Physics. 2025, 44(3):  5.  doi:10.16854/j.cnki.1000-0712.240335

Abstract ( 206 )   PDF (569KB) ( 92 )  

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The motion of microscopic particle in a periodic potential is an important content in the teaching of quantum mechanics and solid state physics. Based on the defective Dirac comb model, this paper studies the energy spectrum structure and typical characteristics of the wave packet scattering in the periodic potential, which can be used as an extension content in the teaching of quantum mechanics, so as to help students establish clear physical picture in the subsequent study of solid state physics.



Investigation on the carrier mobility and thermal conductivity based on Boltzmann equation

TANG Juhong, YANG Kaike, ZHOU Guanghui

College Physics. 2025, 44(3):  8.  doi:10.16854/j.cnki.1000-0712.240179

Abstract ( 352 )   PDF (606KB) ( 476 )  

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The carrier mobility and thermal conductivity are important physical quantities for characterizing the ability of conducting electricity and heat of semiconducting materials and devices. In this work, we describe the method of solving the electron and hole mobilities and the lattice thermal conductivity based on the Boltzmann equation, and then used it to simulate the transport properties of bulk Si and monolayer MoS2. Combined with first-principle calculations, we reveale that both the carrier mobility and thermal conductivity of Si and monolayer MoS2 decreases as temperature rises, in accordance with the experimental results. In addition, we have found that when the carrier concentration is less than 1018 cm-3 or 1012 cm-2, the carrier mobility of Si and MoS2 is almost constant; however, as the carrier concentration is higher than 1018 cm-3 or 1012 cm-2, the carrier mobility of Si and MoS2 is decreasing as the carrier concentration increases. This study, by applying the Boltzmann equation to crystal materials calculations, should be beneficial to promote the teaching and scientific research mutually and collaboratively development.



Extensive investigation on calculation of isochoric molar heat capacity for non-ideal gases

DING Sheguang

College Physics. 2025, 44(3):  14.  doi:10.16854/j.cnki.1000-0712.240317

Abstract ( 254 )   PDF (635KB) ( 634 )  

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Calculation of isochoric molar heat capacity refers to extensive utilization of chemical thermodynamics, numeric analysis, computer programming and so on, which is favorable for cultivation of students’ comprehensive application. Various researches have revealed significant effect of volume (or pressure) on isochoric molar heat capacity of non-ideal gases. On basis of non-ideal gaseous state equations, the isochoric molar heat capacity CV at (p2, T) is calculated under the condition of experimentally or literarily known CV at (p1, T). Comparison between calculation values and literature ones is carried out. The results show that CV is affected considerably by pressure at low temperatures (<400K) and high pressures (>10MPa); effect of elevated pressure can not be ignored, whereas CV is affected slightly at high temperatures or low pressures 



Exploring the microscopic mechanism of liquid surface tension from the  principles of solid surface physics

ZHOU Hua1, QIN Ran2, XU Jinpeng1, GAI Zhigang1, LIU Jianqiang1, LIU Fengqin1

College Physics. 2025, 44(3):  24.  doi:10.16854/j.cnki.1000-0712.240332

Abstract ( 373 )   PDF (1041KB) ( 249 )  

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 Whether in high school or university physics education，students often find it difficult to understand the microscopic mechanism of liquid surface tension. Currently，it is also challenging to observe the microscopic structure of the surface experimentally，making the revelation of the microscopic mechanism of liquid surface tension a persistent scientific problem. To gain a deeper understanding and exploration of this scientific issue，based on the basic principles analogous to solid surface reconstruction and through dynamic simulation methods，we explore that liquid surface tension arises from the increased intermolecular distances in the liquid surface layer，with molecules exhibiting attractive forces between each other. Therefore，there exists a tangential tension on the surface.



Analysis of Brillouin zone folding method for band structures

WU Zongshuo, LI Xu, ZHANG Haijun, YANG Yurong

College Physics. 2025, 44(3):  29.  doi:10.16854 /j.cnki.1000-0712.240337

Abstract ( 470 )   PDF (1058KB) ( 394 )  

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Electronic band structure is a key property in solid materials. It is the connecting lines of energy eigenvalues of the high symmetric points in the Brillouin zone. As the twodimensional layered structure is rolled into a tubular structure, the corresponding reciprocal space will also transform from two dimension to one dimension. Therefore, the energy band of a onedimensional structure can be obtained by folding the corresponding twodimensional Brillouin zone. In this paper, the Brillouin zone folding method of band structure is discussed from two examples, graphene and singlewalled carbon nanotubes, as well as the twodimensional La3Ni2O7 layered structure and its corresponding nanotubes by rolling the La3Ni2O7 layer.



A proof to the Ampereloop theorem of the stable magnetic field

GUAN Congsen1, ZHANG Guangming1, SU Dezhi2, ZHAO Yueyue3

College Physics. 2025, 44(3):  33.  doi:10.16854/j.cnki.1000-0712.240407

Abstract ( 297 )   PDF (528KB) ( 193 )  

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 With the help of Stokes theorem in advanced mathematics，the physical model of current lines and the principle of superposition of field strength，we give a proof method of ampere loop theorem of stable magnetic field，which is different from the proof method of solid angle used in electromagnetism textbooks，and is also different from the proof process in electrodynamics textbooks. Compared with the classic professional textbooks，although the proof process in this paper is more cumbersome，it provides a different approach for the proof of the Ampere loop theorem，which is for the reference of teachers and students.



Theoretical simulation and design of polarization dependent dynamically  tunable fiber filter

LV Zhiguo, LI Ze, JIANG Songyu, WANG Weiwei

College Physics. 2025, 44(3):  36.  doi:10.16854/j.cnki.1000-0712.240293

Abstract ( 189 )   PDF (595KB) ( 124 )  

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Optical Filter can dynamically regulate the spectral bandwidth are of excellent value in laser technology，fiber communication，and other research and application fields. For example，the generation of ultrashort pulsed laser is mainly affected by parameters such as nonlinear phase shift，group velocity dispersion and spectral bandwidth. Among them，the filter bandwidth plays an important role for improving laser parameters such as single pulse energy，pulse width and average power. However，the filter bandwidth used in the generation of ultrashort pulse lasers is fixed，and it is not possible to realize real-time online dynamic tuning of the laser parameters. Aiming at solving the problems that the available filters cannot realize dynamic tuning of the laser spectrum，and the fabrication process is also complicated. This work carries out the theoretical simulation and design of the all-fiber optic filters.



Computer simulation and simple application of one-dimensional  particle scattering problems

WANG Zhe, CHEN Liang

College Physics. 2025, 44(3):  42.  doi:10.16854/j.cnki.1000-0712.240329

Abstract ( 201 )   PDF (850KB) ( 89 )  

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In (elementary) quantum mechanics, one-dimensional particle scattering is quite important. Due to the computational complexity of quantum mechanics, few models can clearly and intuitively qualitatively understand the whole process of one-dimensional particle scattering without manual solving, and even many models cannot obtain an analytical solution. Through computer simulation, it is not only possible to obtain the most accurate numerical solution in a very short time, but also to intuitively understand the process of one-dimensional scattering in the form of images and animations. In addition, through the simulation and analysis of several common examples, the understanding of one-dimensional scattering problems can be effectively deepened.



Virtual Simulation of Beta Ray Absorption

WANG Dong1, ZHANG Min1, HAN Xiao-xi2, CHENG Bin2

College Physics. 2025, 44(3):  48.  doi:10.16854/j.cnki.1000-0712.240114

Abstract ( 243 )   PDF (621KB) ( 62 )  

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 As one of the important phenomena in nuclear physics, the principle of beta ray absorption experiment is widely used in production and medical fields. However, due to the limitations of specific experimental conditions, it is difficult to carry out relevant physics experiments in the universities. The beta ray absorption experiment process is simulated and developed by Monte Carlo calculation software Geant4. By Monte Carlo simulation method and 3D simulation technology, the characteristics of beta ray absorption is studied in the 3D simulation environment. By analyzing the absorption data of aluminum absorption plates on 137Cs radiation sources, it is found that the absorption coefficient method is closer to the theoretical value compared to the maximum range method. The energy loss per unit mass thickness is greater with the greater atomic number of a material. The virtual simulation of beta ray absorption enables the students to understand the absorption law of beta ray. At the same time, it cultivates the students' operational capacity and innovative thinking.



Refractiveindex measurement experimental system based on phase-sensitive  spectral interferometry

ZHOU Hong-xian, WANG Yi

College Physics. 2025, 44(3):  53.  doi:10.16854/j.cnki.1000-0712.240198

Abstract ( 222 )   PDF (657KB) ( 96 )  

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A refractive index measurement method and an experimental system based on spectral domain interference have been established, which mainly includes a fiber-optic Michelson interferometer, a spectrometer, linear fitting and phase unwrapping methods. Interference signals are collected by the spectrometer, and high-precision optical path lengths are obtained using linear fitting and phase unwrapping methods, thereby calculating the refractive index. Using this system, the refractive indices of silicon wafers, N-BK7 glass, and distilled water are measured to be 3.511±0.012, 1.508±0.019, and 1.311±0.022, respectively. The relative errors are 0.23%, 0.33%, and 0.37%, respectively. This method enables refractive index measurements of transparent and translucent solid and liquid samples without the need for special sample treatment, showing a new development and application of interferometry technology.




Design of Fourier ptychographic microscopy imaging teaching platform  based on MATLAB GUI

LUO Jia-xiong1, LUO Zi-cong1, WU Yan-xiong1, 2, LIU Ming-di1, LIANG Jun-zhao1, XIE Rui1

College Physics. 2025, 44(3):  57.  doi:10.16854/j.cnki.1000-0712.240324

Abstract ( 227 )   PDF (1941KB) ( 148 )  

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Fourier ptychographic microscopy (FPM) is a new computational imaging technology, which has the advantages of large field of view, high resolution and quantitative phase imaging, and has good application prospects in many fields. In the FPM experiment and teaching, it is difficult for students to intuitively understand the influence of different parameters, errors and algorithms on the FPM experiment results. Therefore, the FPM experiment and teaching platform is developed by using MATLAB GUI. Using this platform, students can set different recovery parameters and misalignment errors by themselves and use a variety of reconstruction algorithms to conduct simulation experiments, explore the impact of parameters, errors and algorithms on the quality of FPM reconstruction, and improve their understanding of FPM. The experimental platform mainly includes basic parameter setting module, iterative recovery module and result display module. It has the advantages of simple operation and rigorous structure, and can effectively improve the teaching efficiency of FPM.




Research on the application of HTML5 numerical simulations in  optics teaching

WANG Xi-guang, FU Lin, CHENG Yu, PAN Shuo-ming, ZHANG Ming-hao

College Physics. 2025, 44(3):  64.  doi:10.16854/j.cnki.1000-0712.240331

Abstract ( 215 )   PDF (790KB) ( 756 )  

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This study develop an interactive HTML5 optical numerical simulation and explore its applications within optics teaching. The interface design allows students to visually observe the impact of changes in optical parameters on simulation outcomes. We introduce optical simulation exercises featuring random parameters to personalize learning experience. Utilizing the cross-platform capabilities and interactive features of HTML5, this program enables convenient learning and practical activities for students at any time and place. Through three classic optical cases—geometric optical imaging, Young's double-slit interference, and Fresnel circular aperture diffraction as examples, we demonstrate the design philosophy and application value of our HTML5-based optical numerical simulation teaching tool. 



The practice and reflection on Matlab visualization course  assisted electrodynamics teaching

LI Ya-juan, SHEN Jiao-yan, SUN Jian, CHEN Yong-qiang, CHEN Gao-yuan, MA Chun-lan

College Physics. 2025, 44(3):  70.  doi:10.16854/j.cnki.1000-0712.240339

Abstract ( 266 )   PDF (951KB) ( 550 )  

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In order to make it easier for students to  understand abstract and complex physical concepts in electrodynamics and to stimulate their interest in independent learning and exploration, our  team has adopted practical teaching courses, which account for 40% of the total, to teach students to implement the visualization of basic knowledge and cutting-edge scientific applications in electrodynamics through Matlab. Based on the fundamental theories of electrostatic fields, magnetic fields, and the propagation of electromagnetic waves, drawing cases with clear physical significance and moderate difficulty are designed to help students consolidate the theoretical derivation from traditional classroom teaching, deepen students' understanding of the laws governing electromagnetic fields and, at the same time, cultivate their ability to address real-world problems by integrating electrodynamics knowledge  with tools such as Matlab, thereby elevating the educational quality on various fronts.




Ideological and political teaching design practice in fluid mechanics——Taking Dujiangyan irrigation project as an example

SHEN Feng, ZHANG Jie, LIU Zhaomiao, PANG Yan

College Physics. 2025, 44(3):  76.  doi:10.16854/j.cnki.1000-0712.240361

Abstract ( 318 )   PDF (475KB) ( 1334 )  

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Fluid mechanics as a physics branch and a basic course is widely studied in universities, which plays an important role in the ideological and political education in promoting scientific spirit and shaping value orientation. How to integrate ideological and political elements into classroom teaching to arouse students resonance has become the key for teachers. Taking Dujiangyan irrigation project as a specific teaching case, this paper discusses how to establish the ideological and political teaching case of fluid mechanics, including case content, instructional design, case features, and feedback. This teaching case aiming at making students feel and resonate and providing useful inspiration and reference for the ideological and political teaching of basic courses. 



Integrating first-principles calculations into semiconductor physics education

LING Faling, LILi, CHEN Jiangshan

College Physics. 2025, 44(3):  80.  doi:10.16854/j.cnki.1000-0712. 240377

Abstract ( 380 )   PDF (1258KB) ( 1034 )  

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Recent advancements in internet technology and computing have opened new avenues for transforming traditional university physics education. Semiconductor physics, a fundamental aspect of these courses, stands to gain significantly from modern, innovative teaching approaches. This paper explores the integration of advanced first-principles computational methods with single-crystal silicon materials to enhance the quality and effectiveness of semiconductor physics instruction. By elucidating the theoretical foundations of first-principles calculations and their practical applications in teaching semiconductor crystal structures, electronic properties, impurities, and defects, this study provides practical insights and theoretical support for reforming semiconductor physics education. The aim is to improve educational outcomes and foster greater student engagement and creativity in the field.




The probe and practice of the teaching mode of  postgraduate courses combining teaching and research

ZHANG Guofeng

College Physics. 2025, 44(3):  84.  doi:10.16854/j.cnki.1000-0712. 240157

Abstract ( 213 )   PDF (1336KB) ( 174 )  

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Deepening the teaching reform, exploring and constructing the new teaching system of the research-oriented university, and cultivating high-quality talents with international competitiveness are inseparable from the construction of graduate courses. The postgraduate courses should aim at improving the academic and innovative ability of the postgraduate students. On the basis of respecting and stimulating the learning interest of the students, the research ability of the course content, the research ability of the learning style, the research ability of the integration of ideology and politics should be strengthened, and the cultivation of innovative thinking and scientific methods should be strengthened. In the past ten years, the author has taught quantum optics in Beijing University  of Aeronautics and Astronautics, and through the gradual change of teaching concept, teaching content and teaching method, and the radiation extension to other courses, the author has formed some thoughts on the construction of graduate courses. The author believes that postgraduate courses should take stimulating scientific research potential as the fundamental purpose, guided and guided reading of classical literature as the characteristics, build research-oriented teaching mode exploration and practice as the starting point, take scientific problems as the fulcrum of interest, take in-class and extra-class process evaluation as the assessment index, and create an educational atmosphere encouraging inquiry as the carrier. We will strengthen the teaching reform and education practice of combining teaching and research.




A scientific master who created the worlds engineering wonders —On the occasion of the 200th anniversary of Kelvins birth

XIE Qihao, LU Jianlong

College Physics. 2025, 44(3):  88.  doi:10.16854/j.cnki.1000-0712.240176

Abstract ( 255 )   PDF (573KB) ( 242 )  

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Kelvin (1824-1907) as the development of classical physics to the most brilliant era of one of the most influential physicists, its life research scope, in thermodynamics, electromagnetism, fluid mechanics, geophysics, mathematics and other aspects have outstanding contribution, known as Britains "Victorian King of Physics". Kelvin is also an outstanding engineer, not only applied for 70 patents, but also in the Atlantic cable of the century project from the design to the laying of the entire participation. Kelvin has a unique temperament of science and engineering technology in harmony, which is exactly what we are now pursuing the goal of talent training. 2024 coincides with the 200th anniversary of the birth of Kelvin, this paper reviews some of Kelvins research experience, to explore its body has a "dual identity" on the revelation of the present day as a commemoration of the Kelvin.



The exploration of the influencing factors of  saturated photocurrent in photoelectric effect

LIU Fengning, ZHENG Xiao, ZHANG Guofeng, DONG Guobo, XU Ping

College Physics. 2025, 44(3):  95.  doi:10.16854/j.cnki.1000-0712.240249

Abstract ( 504 )   PDF (710KB) ( 437 )  

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 In the photoelectric effect experiment, the saturation photocurrent is affected by many factors, including the voltage between the plates, the frequency of the incident light, the intensity of the incident light and the photoelectric efficiency of the cathode material. In order to explore the influence of these factors on saturated photocurrent, we use the control variable experiment method. The experimental results show that the incident light intensity has a linear relationship with the saturation photocurrent until the saturation photocurrent is reached at a certain photoelectric efficiency and frequency. When the incident light frequency and light intensity are fixed, the photoelectric efficiency of the cathode material will be affected when the voltage between the plates is not large enough, and the saturation photocurrent will be affected. When the light intensity and voltage are fixed, the number of photons is different for different frequencies of light, and the saturation photocurrent is directly related to the number of photons. In addition, the photoelectric efficiency of the cathode material is nonlinear with the frequency of the incident light, resulting in a nonlinear relationship between the frequency of the incident light and the saturated photocurrent. To sum up, the saturated photocurrent is the limit value under a specific condition, which is the result of multiple factors.



Demonstrating the relationship between energy level degeneracy and  symmetryusing a spherical acoustic cavity

GONG Yihong, JIA Wenhui, GUO Jinglin, BAI Zaiqiao

College Physics. 2025, 44(3):  100.  doi:10.16854/j.cnki,1000-0712.240195

Abstract ( 187 )   PDF (873KB) ( 153 )  

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We use an empty glass shell with a long neck and study how its eigenfrequency splits after breaking the symmetry. Our goal is to provide an example to show the relation between symmetry and energy degeneracy in quantum mechanics. The system is driven by a swept signal, and we use a microphone to acquire acoustic signals in the glass shell. Then we derive the eigenfrequencies of the shell from the power spectrum. For l=2, if we break the SO(3) symmetry while keeping the SO(2) symmetry, according to experiment, the initial degenerate three eigenfrequencies exhibit into two eigenfrequencies, one of which has two-fold degeneracy. When we continue to break its SO(2) symmetry and keep its discrete reflectional symmetry only, the three eigenfrequencies separate completely. We simulate this progress by applying COMSOL Multiphysics and find the reasons that some eigenfrequencies are insensitive to perturbations in the experiment: these states are odd and have small amplitudes near the neck of the shell.






Gravitational wave data processing based on fundamental mathematics

CHEN Xueling, SUN Haoran, ZHANG Yunxi, HU Yiming

College Physics. 2025, 44(3):  106.  doi:10.16854/j.cnki.1000-0712.240268

Abstract ( 285 )   PDF (820KB) ( 249 )  

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Since the Laser Interferometric Gravitational Wave Observatory detected the gravitational wave event GW150914 in 2015, the gravitatinoal wave window has been opened to explore the Universe. Gravitational wave research has become a hotspot in physics and astronomy, and it helped three gravitational wave experts to win the Nobel Prize in 2017. Although the frontier of gravitational wave research requires advanced methods such as numerical relativity and large-scale high-performance numerical computation, the core principle of gravitational wave data analysis is actually very simple. In this paper, we try to demonstrate the use of simple mathematical principles to analyze gravitational wave data: through the short-time Fourier transform, the time domain gravitational wave data can be transformed into the time-frequency domain; the time-frequency relation of the binary black hole inspiral signal is matched with the data to obtain the most probable value of the mass of the binary dense star, the moment of merger. Comparison with the official results of LIGO shows that the relevant method, although with limited accuracy, the above simple mathematical principle can efficiently extract the physical parameters of the gravitational wave source when the noise behaviour is close to ideal.




Simulation of Michelson’s interference experiments  based on the unity platform

LIU Bin 1, ZHAO Penglin 1, SONG Ye1, WANG Zengxu2, LI Yongtao2

College Physics. 2025, 44(3):  112.  doi:10.16854/j.cnki.1000-0712.240323

Abstract ( 282 )   PDF (673KB) ( 163 )  

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A comprehensive investigation of the physical model of the Michelson interferometer is conducted, culminating in the development of a virtual simulation software for the Michelson interferometer experiment on the Unity platform. By integrating Unity's physics engine with custom algorithms, this simulation software accurately replicates the experimental procedure of the Michelson interferometer. It allows for precise adjustments to the positions of mirrors, mirror orientations, and translation stages, while dynamically displaying the resulting interference patterns. The simulation software enhances the pedagogical experience and facilitates a deeper understanding of optical principles. Test results demonstrate that the simulation's accuracy and outcomes align with those of actual experiments, providing a practical tool for the instruction of Michelson interferometer experiments.