基本情况

姓名

洪学仁

性别

男

出生日期

1975.11

职称

副教授

职务

学院副院长，主管研究生教育工作

研究方向

激光等离子体物理

籍贯

甘肃通渭

工作单位

西北师范大学

地址

西北师范大学物理与电子工程学院

电话

(0931)7970361

电邮

hongxr@nwnu.edu.cn

教育背景及主要工作经历

教育背景:

2008-09至2012-01，北京师范大学，核科学与技术学院，博士，导师：谢柏松 教授，专业：理论物理。

2000-09至2003-06, 西北师范大学，物理与电子工程学院，硕士，导师：孙建安 教授、段文山 教授、吕克璞 教授，专业：原子与分子物理。

1996-09至2000-06, 西北师范大学，物理系，本科，专业：物理学。

主要工作经历：

2012-03至现在，西北师范大学，物理与电子工程学院，副教授，硕士生导师。

2006-07至2012-02，西北师范大学，物理与电子工程学院，讲师。

行政和社会兼职工作

2017.01起，担任学院副院长，主管研究生教育工作。

教学工作

本科教学：

1. 主讲本科生的“高等数学I”、“高等数学II”、“普通物理专题”等课程。负责的“高等数学I”课程入选省级一流本科课程和校级思政示范课程，作为主要成员的“高等数学系列课程教学团队”入选省级教学团队。

2. 近5年主持教育部产学合作协同育人项目3项；主持完成各类校级教学研究项目3项。

3. 近5年指导全国大学生数学建模竞赛、全国大学生数学竞赛、“格致杯”物理师范生教学技能大赛、蓝桥杯全国软件和信息技术专业人才大赛、“华夏杯”全国物理教学创新大赛、“九斗杯”西部高校大学物理竞赛等竞赛获省级以上奖励30余项。

研究生教学：

主讲研究生的“激光等离子体物理”、“前沿专题选讲”等课程。目前在“等离子体物理”和“理论物理”专业招收和培养硕士研究生。

科研项目

1. 目前主持国家自然科学基金项目1项(q-高斯激光和暗空心高斯激光在等离子体通道中的传播及辐射特性研究，12165018，2022.01-2025.12)。

2. 主持完成国家自然科学基金项目2项(①西北师范大学理论物理专业激光等离子体物理研究方向学术交流与人才培养平台建设，12047574，2021.01-2021.12；②强激光与等离子体相互作用加速高品质离子束的理论与粒子模拟研究，11365020, 2014.01-2017.12)；参加完成国家自然科学基金项目5项。

3. 主持完成甘肃省高等学校基本科研业务费项目1项(极端条件下电子、离子及原子动力学特性研究，2013.01-2015.12)，西北师范大学青年基金项目1项(尘埃等离子体中的非线性波研究，NWNU-QN-04-26)。

获奖情况

荣誉称号：

西北师范大学首届“青年教师教学科研之星”（双星）(2014.4)。

教学获奖：

1. 两次获西北师范大学学生心目中的“优秀教师”称号(第二届，2005.9；第三届，2007.9)。

2. 两次获西北师范大学教学质量优秀奖(2005-2006学年度，2006.8；2007年度，2007.11)。

科研获奖：

1. 若干非线性现象的理论研究，2016年甘肃省高等学校科研优秀成果三等奖，段文山教授主持，本人排名第五，2016年10月。

2. 多粒子系统中若干非线性物理问题研究，2014年甘肃省高校科技进步二等奖，段文山教授主持，本人排名第七，2014年9月。

3. 极端条件下若干复杂物理体系的动力学研究，2012年甘肃省高校科技进步一等奖，段文山教授主持，本人排名第二，2012年8月。

4. 基于摄动方法的复杂系统中非线性行为的研究，2010年甘肃省自然科学二等奖，段文山教授主持，本人排名第四，2011年1月。

5. 高维系统中多粒子体系相互作用研究，2010年甘肃省高校科技进步二等奖，段文山教授主持，本人排名第四，2010年8月。

6. 多组份尘埃等离子体及其相关系统的非线性研究，2008年甘肃省高校科技进步二等奖，段文山教授主持，本人排名第四，2008年7月。

7. 摄动方法在求解复杂物理问题中的应用，2006年甘肃省高校科技进步奖一等奖，段文山教授主持，本人排名第四，2006年7月。

8. 连续介质物理中多种线性与非线性声波及其稳定性问题研究，2002-2003年度甘肃省高校科技进步奖一等奖，2004年7月；2004年甘肃省科技进步二等奖，2005.4。段文山教授主持，本人排名第六。

发表论文目录

[1] Xue-Ren Hong*(洪学仁), Yu-Yu Shi, Li-Peng Wang, De-Sheng Zhang, Xiao-Bo Zhang, Lie-Juan Li, Rong-An Tang, and Jian-An Sun, Influence of magnetic fields of lasers on generation of terahertz radiation by interaction of two-color lasers with plasmas, Phys. Plasmas 31, 073109(2024).

[2] Xue-Ren Hong*(洪学仁), Ke Shi, Shi-Ya Liang, Lie-Juan Li, and Rong-An Tang, Generation of terahertz radiation through nonlinear Thomson scattering by two moderate-intensity laser fields, Phys. Plasmas 31, 073102(2024).

[3] De-Sheng Zhang, Xue-Ren Hong*(洪学仁), Xiao-Bo Zhang,Rong-An Tang, and Bai-Song Xie, Generation of the vortex terahertz radiation by the interaction of two-color Laguerre–Gaussian laser with plasmas in the presence of a static magnetic field, Phys. Plasmas 31, 073107(2024).

[4] Kang-Ming Ren, Cang-Long Wang*, Ji-Tao Liu, Ya-Feng Shu, Hao-Hao Zhang, Pan-Li Qi, Xue-Ren Hong*(洪学仁), and Qing-Qing Liang, Screening and optimization of metal-insulator-metal selective emitter in thermophotovoltaic system, Mod. Phys. Lett. B 38, 2450145(2024).

[5] Xue-Ren Hong*(洪学仁), Ya-Nan Li, Dou Wei, Rong-An Tang, Jian-An Sun, and Wen-Shan Duan, Even-order harmonic generation from nonlinear Thomson backscatter in a tightly focused Gaussian laser pulse, Phys. Plasmas 29, 043102(2022).

[6] Xue-Ren Hong*(洪学仁), Ke Shi, Ya-Nan Li, Dou Wei, Rong-An Tang, Jian-An Sun, and Wen-Shan Duan, Response to “Comment on ‘Even-order harmonic generation from nonlinear Thomson backscatter in a tightly focused Gaussian laser pulse’”[Phys. Plasmas 29, 114703 (2022)], Phys. Plasmas 29, 114704(2022).

[7] Xue-Ren Hong*(洪学仁), Dou Wei, Ya-Nan Li, Rong-An Tang, Jian-An Sun*, and Wen-Shan Duan, Enhanced radiation of nonlinear Thomson backscattering by a tightly focused Gaussian laser pulse and an external magnetic field, EPL(Europhysics Letters) 139, 14001(2022).

[8] Xue-Ren Hong*(洪学仁), Hui-Qi Li, Dou Wei, Ya-Nan Li, Rong-An Tang, Jian-An Sun*, and Wen-Shan Duan, Reply to the Comment by Yubo Wang et al., EPL(Europhysics Letters)  141,34002(2023).

[9] Xue-Ren Hong(洪学仁), De-Sheng Zhang, Ji-Ming Gao, Rong-An Tang*, Peng Guo, and Ju-Kui Xue, The propagation dynamics and stability of an intense laser beam in a radial power-law plasma channel, Plasma Sci. Technol. 23, 125002(2021).

[10] Xue-Ren Hong(洪学仁), Wei Sun, Mierk Schwabe, Cheng-Ran Du*,  and Wen-Shan Duan*, Reflection and transmission of an incident solitary wave at an interface of a binary complex plasma in a microgravity condition, Phys. Rev E 104, 025206(2021).

[11] Xue-Ren Hong(洪学仁), You-Lian Zheng*, Rong-An Tang, Tiao-Fang Liu, and Xiao-Ping Liu; Propagation characteristics of a hollow Gaussian laser beam in a tapered plasma channel, Phys.Plasmas 27, 043109(2020).

[12] Rong-An Tang*, Li-Ru Yin, Xue-Ren Hong(洪学仁), Ji-Ming Gao, Li-Hong Cheng, and Ju-Kui Xue, Propagation dynamics of an azimuthally polarized Bessel–Gauss laser beam in a parabolic plasma channel, Phys. Plasmas  27, 113103(2020).

[13] Rong-An Tang*, Rui-Jin Cheng, Xue-Ren Hong(洪学仁), Tiao-Fang Liu, Xiao-Xun Li, Ji-Ming Gao, Peng Guo, Jian-Min Tian, and Ju-Kui Xue, Effects of channel alternating corrugation on a laser beam propagation in plasmas, Phys. Lett. A 384, 126267(2020).

[14] Lei Zhang, Rong-An Tang*, Xue-Ren Hong(洪学仁), Ji-Ming Gao,  Li-Ru Yin, Jian-Min Tian,  Rui-Jin Cheng, and Ju-Kui Xue, A filter or oscillator by a simple density hump for an intense laser propagating in a preformed plasma channel, Phys. Plasmas 26, 043106(2019).

[15] Wei-Jun Zhou, Xue-Ren Hong*(洪学仁), Bai-Song Xie, Yang Yang, Li Wang, Jian-Min Tian, Rong-An Tang, and Wen-Shan Duan, High quality ion acceleration through the interaction of two matched counterpropagating transversely polarized Gaussian lasers with a flat foil target, Phys. Rev. Accel. beams 21, 021301(2018).

[16] Xue-Ren Hong*(洪学仁), Min Jing, Yu-Ren Shi, and Li-Hong Chen,  Intense laser propagation in an inhomogeneous magnetized electron-positron-ion plasma, Journal of Northwest Normal University(Natural Science) 54(3), 33(2018). (in Chinese)

[17] Jian-An Sun, Li Wang, Xue-Ren Hong*(洪学仁), Yang Yang, and Rong-An Tang, Solitary waves of q-Gaussian laser beam in a preformed plasma channel, Journal of Northwest Normal University(Natural Science) 53(3), 34(2017). (in Chinese)

[18] Li Wang, Xue-Ren Hong*(洪学仁), Jian-An Sun*, Rong-An Tang, Yang Yang, Wei-Jun Zhou, Jian-Min Tian, and Wen-Shan Duan, Effects of relativistic and channel focusing on q-Gaussian laser beam propagating in a preformed parabolic plasma channel, Phys. Lett. A 381, 2065(2017).

[19] Xue-Ren Hong(洪学仁), Wei-Jun Zhou*, Bai-Song Xie, Yang Yang; Li Wang, Jian-Min Tian, Rong-An Tang, and Wen-Shan Duan; Generation of high quality ion beams through the stable radiation pressure acceleration of the near critical density target, Chin. Phys. B 26, 065203(2017).

[20] Heng Zhang, Yang Yang, Xue-Ren Hong(洪学仁), Xin Qi, Wen-Shan Duan*, and Lei Yang*, Freak oscillation in a dusty plasma, Phys.Rev. E 95, 053207(2017).

[21] Chong Lv, Feng Wan, Ya-Juan Hou, Xue-Ren Hong(洪学仁), Mo-Ran Jia, Hai-Bo Sang, and Bai-Song Xie*, Accelerating and guiding of C6+ by an intense laser irradiating on a foil target with a tapered channel, Phys. Plasmas 24, 083114(2017).

[22] Chong Lv, Bai-Song Xie*, Feng Wan, Ya-Juan Hou, Mo-Ran Jia, Hai-Bo Sang, Xue-Ren Hong(洪学仁), and Shi-Bing Liu, Enhanced laser radiation pressure acceleration of protons with a gold cone-capillary, Phys. Plasmas 24, 033122(2017).

[23] Jian-Min Tian, Rong-An Tang*, Xue-Ren Hong(洪学仁), Yang Yang, Li Wang, Wei-Jun Zhou, and Ju-Kui Xue, The characteristics of an intense laser beam propagating in a corrugated plasma channel, Phys. Plasmas 23, 123117(2016).

[24] Rong-An Tang*, Xue-Ren Hong(洪学仁), Ji-Ming Gao, and Ju-Kui Xue, Focusing effect of radially power-law channel on an intense laser beam, Phys. Lett. A 380, 1037(2016).

[25] Zhong-Zheng Li, Heng Zhang, Xue-Ren Hong(洪学仁), Dong-Ning Gao, Jie Zhang, Wen-Shan Duan*, and Lei Yang*, PIC simulation of compressive and rarefactive dust ion-acoustic solitary waves, Phys. Plasmas 23, 082111(2016).

[26] Heng Zhang, Yang Yang, Jie Zhang, Xue-Ren Hong(洪学仁), Mai-Mai Lin, Lei Yang, Xin Qi*, and Wen-Shan Duan*, Landau damping in a multi-component dusty plasma, Phys. Plasmas 21, 113706(2014).

[27] Dong-Ning Gao, Xin Qi, Xue-Ren Hong(洪学仁), Xue Yang, Wen-Shan Duan*, and Lei Yang*, The stability of the dust acoustic waves undertransverse perturbations in a magnetized and collisionless dusty plasma, J. Plasma Physics 80, 425(2014).

[28] Dong-Ning Gao, Xue-Ren Hong(洪学仁), Mai-mai Lin, Juan-fang Han, Wen-shan Duan*, and Lei Yang*, Effects of the relative motion of different particles on the wave instability in dusty plasmas, Phys. Plasmas 21, 062110(2014).

[29] Shi-Wei Liu, Xin Qi, Jiu-Ning Han, Xue-Ren Hong(洪学仁), Yu-Ren Shi, Wen-Shan Duan*, and Lei Yang*, Interaction for solitary waves in coasting charged particle beams. Phys. Plasmas 21, 033106(2014).

[30] Xue Yang, Juan-Fang Han, Cong-Bo Liu, Yu-Ren Shi, Sheng-Qian Ma, Xue-Ren Hong(洪学仁), Wen-Shan Duan*, and Lei Yang*, The effects of the ionization, the recombination, and the collision of the ions to the damping solitary waves in a dusty plasma, Phys. Plasmas 20, 023704 (2013).

[31] Ji-Zheng Duan, Cang-Long Wang, Jian-Rong Zhang, Sheng-Qian Ma, Xue-Ren Hong(洪学仁), Jian-An Sun, Wen-Shan Duan*, and Lei Yang*, Influence of charging process and size distribution of dust grain on the electric conductivity of dusty plasma, Phys. Plasmas 19, 083703(2012).

[32] Muhammad-Ali Bake, Shan-Zhang, Bai-Song Xie*, Xue-Ren Hong(洪学仁), and Hong-Yu Wang, Energy enhancement of proton acceleration in combinational radiation pressure and bubble by optimizing plasma density, Phys. Plasmas 19, 083103 (2012).

[33] Xue-Yan Zhao, Bai-Song Xie*, Hai-Cheng Wu, Shan Zhang, Xue-Ren Hong(洪学仁), and Aimierding Aimidula, Electron injection and acceleration in the plasma bubble regime driven by an ultraintense laser pulse combined with using dense-plasma wall and block, Phys. Plasmas 19, 033108 (2012).

[34] Xue-Ren Hong(洪学仁), Bai-Song Xie*, Shan Zhang, Hai-Cheng Wu, and Xue-Yan Zhao, Wakefield effects and solitary waves of an intense short laser pulse propagation in a plasma channel, Phys. Plasmas 18,103106(2011).

[35] Shan Zhang, Xue-Ren Hong(洪学仁), Hong-Yu Wang, and Bai-Song Xie*, Allowable propagation of short pulse laser beam in a plasma channel and electromagnetic solitary waves, Phys. Lett. A 375, 4022(2011).

[36] Shan Zhang, Bai-Song Xie*, Xue-Ren Hong(洪学仁), Hai-Cheng Wu, and Xue-Yan Zhao, Solitary waves of laser pulse in a plasma channel, Phys. Plasmas 18, 033104(2011).

[37] Shan Zhang, Bai-Song Xie*, Xue-Ren Hong(洪学仁), Hai-Cheng Wu, Aimierding Aimidula, Xue-Yan Zhao, and Ming-Ping Liu, Suppression of multiple ion bunches and generation of monoenergetic ion beams in laser foil-plasma, Chin. Phys. B 20, 015206(2011).

[38] Hai-Cheng Wu, Bai-Song Xie*, Shan Zhang, Xue-Ren Hong(洪学仁), Xue-Yan Zhao, and Ming-Ping Liu, Bubble core field modification by residual electrons inside the bubble, Phys. Plasmas 17, 113103(2010).

[39] Xue-Ren Hong(洪学仁), Bai-Song Xie*, Shan Zhang, Hai-Cheng Wu, Aimierding Aimidula, Xue-Yan Zhao, and Ming-Ping Liu, High quality ion acceleration from a double-layertarget dominated by the radiation pressure of a transversely Gaussian laser pulse, Phys. Plasmas 17,103107(2010).

[40] Jun Li, Bai-Song Xie*, Hai-Bo Sang, Xue-Ren Hong(洪学仁), Shan Zhang, and M. Y. Yu, Nonlinear laser-driven electron resonance acceleration in an inhomogeneous magnetic field, Appl. Phys. Lett. 95, 161105(2009).

[41] Ming-Ping Liu, Hai-Cheng Wu, Bai-Song Xie*, Xue-Ren Hong(洪学仁), Shan Zhang, and M. Y. Yu, Electron acceleration by intense short laser pulse in the preplasma of a target, Phys. Plasmas 16, 083104(2009).

[42] Hai-Cheng Wu, Bai-Song Xie*, Ming-Ping Liu, Xue-Ren Hong(洪学仁), Shan Zhang, and M. Y. Yu, Electron trajectories and betatron oscillation in the wake bubble in laser-plasma interaction, Phys. Plasmas 16, 073108(2009).

[43] Cang-Long Wang, Wen-Shan Duan*, Xue-Ren Hong(洪学仁), and Jian-Min Chen, Investigation of superlubricity in a two-dimensional Frenkel–Kontorova model with square lattice symmetry. Appl. Phys. Lett. 93, 153116(2008).

[44] Xiu-Yun Gao, Xue-Ren Hong(洪学仁), Cang-Long Wang, and Wen-Shan Duan*, The dynamic characters of excitations in an one-dimensional Frenkel-Kontorova model. Chin. Phys. B 17, 3378(2008).

[45] Chang Lin*, Xue-Ren Hong(洪学仁), and Fu-Quan Dou, Analytical studies of the steady solution for optical soliton equation with higher-order dispersion nonlinear effects. Commun. Nonlinear Sc. 13, 567(2008).

[46] Xue-Ren Hong*(洪学仁), Wen-Shan Duan, Jian-An Sun, Yu-Wei Fu, Xiao-Xian Yang, and Ai-Xia Mu, Modulational instability of dust-acoustic waves in a warm dusty plasma, Journal of Northwest Normal University(Natural Science) 41(6), 62(2005). (in Chinese)

[47] Wen-Shan Duan*, Lei Zhang, Mai-Mai Lin, Xue-Ren Hong(洪学仁), and Ke-Pu Lü, Cylindrical higher order disturbances to planar solitary waves, Chaos, Solitons and Fractals 26,325(2005).

[48] Wen-Shan Duan*, Yu-Ren Shi, and Xue-Ren Hong(洪学仁), Theoretical study of resonance of the Kadomtsev- Petviashivili equation, Phys. Lett. A 323, 89(2004).

[49] Wen-Shan Duan*, Xue-Ren Hong(洪学仁), Yu-Ren Shi, and Jian-An Sun, Envelop solitons in dusty plasmas for warm dust, Chaos, Solitons and Fractals 16, 767(2003).

[50] Xue-Ren Hong(洪学仁)，Wen-Shan Duan*, Jian-An Sun, Yu-Ren Shi, and Ke-Pu Lv, The propagation of solitons in an inhomogeneous dusty plasma, Acta Phys. Sin. 52(11), 2671(2003). (in Chinese)

[51] Wen-Shan Duan*, and Xue-Ren Hong(洪学仁), Ion acoustic solitary waves in a weakly relativistic plasma under transverse perturbations, Acta Phys. Sin. 52(6), 25 (2003). (in Chinese)

[52] Wen-Shan Duan*, Xue-Ren Hong(洪学仁), Yu-Ren Shi, Ke-Pu Lv, and Jian-An Sun, Weakly two dimensional solitary waves on coupled nonlinear transmission lines, Chin. Phys. Lett . 19, 1231(2002).

[53] Wen-Shan Duan*, Yu-Ren Shi, Xue-Ren Hong(洪学仁), Ke-Pu Lv, and Jin-Bao Zhao, The reflection of soliton at multi-arterial bifurcations, Phys. Lett. A 295, 133(2002).

[54] Yu-Ren Shi*，Xue-Ren Hong(洪学仁)，Wen-Shan Duan, Jin-Bao Zhao, and Ke-Pu Lü, The exact solutions to the equation of nonlinear vibrating string, Journal of Northwest Normal University(Natural Science) 38(2), 51(2002). (in Chinese)

[55] Ke-Pu Lv*，Xue-Ren Hong(洪学仁), Yu-Ren Shi, and Jian-An Sun, Variational principles and reductive perturbation approach to nonlinear vibrating string, Journal of Northwest Normal University(Natural Science) 37(4), 35(2001). (in Chinese)