王汉权

信息来源: 作者:  发布时间:2023-03-21

1. 个人简介

王汉权,19742月出生,博士,博士生导师教育部新世纪优秀人才中国数学会计算数学分会常务理事,云南省中青年学术带头人云南省数学会常务理事云南省数学类专业教学指导委员会委员,四川大学数学学院兼职博士生导师。

Email: hanquan.wang@gmail.com wang_hanquan@hotmail.com

2. 研究方向

主要从事科学研究的领域包括计算数学与科学工程计算,各种偏微分方程、随机偏微分方程的数值解法(有限差分法、谱方法、谱元法等)的设计与应用,泛函极值问题求解方法设计与应用,最优化理论方法与应用,计算机模拟玻色-爱因斯坦凝聚态中的涡旋现象和材料科学中的晶体位错现象。


3. 受教育经历

19929-19967,  华中师范大学数学系,本科,理学学士

19999-20024,  北京理工大学应用数学系,研究生,理学硕士

20028-20063,  新加坡国立大学数学系,研究生,计算数学专业博士


4. 研究工作经历

20064-2006 9,  新加坡国立大学数学系, 研究助理

200610-20078, 香港科技大学数学系, 访问学者(博士后)

20087-20088,  香港科技大学数学系,  访问学者

20091-20092,  新加坡国立大学数学系,  研究学者

20097-20098,  新加坡国立大学数学系,  资深研究学者

2011426-201151日,中国科学院物理研究所,访问学者(访问刘伍明教授)

20117-20121,  香港科技大学数学系,   访问学者

20077-20087,  统计与数学学院, 讲师

20088-20118,  统计与数学学院, 副教授

20118-201512,   统计与数学学院, 教授

201611---至今,  特聘教授

20125月,入选云南省科技厅第十五批中青年学术带头人后备人才

20127月,被聘为教育部留学回国人员科研启动基金评审专家

201274-2012722日,北京大学数学学院,访问学者(访问张平文教授)

201394日,入选教育部2013年度新世纪优秀人才

20131215--20131231日, 北京计算科学研究中心,访问教授

2014731日,获得云南省有突出贡献优秀专业技术人才称号, 三等奖

2014920---2015315日, 美国纽约哥伦比亚大学应用物理与数学系,访问学者

20155月,国家自然科学基金面上项目通信评审专家

20155月,云南省科技厅中青年学术带头人后备人才评审专家

2016731---2016811日,复旦大学数学学院,高级访问学者

201781---2017811日,复旦大学数学学院,高级访问学者

2017年获得云南省自然科学奖三等奖一项

2017年获得云南省中青年学术带头人称号


5. 主持科研项目

[1]  国家自然科学基金面上项目(项目编号11871418,项目经费52万),2019/01-2022/12,主持

[2] 国家自然科学基金重大计划项目培育项目 (项目编号91430103,项目经费60万),2014年立项,结题

[3] 教育部2013年度新世纪优秀人才支持基金(项目经费50万),2013年立项,2017年结题

[4] 云南省科技厅第十五批中青年学术带头人后备人才(项目经费12万),2012年立项,2017年结题

[5] 国家自然科学地区基金(项目编号11261065,项目经费45万),2012年立项,,2016年结题

[6] 国家自然科学青年基金(项目编号10901134,项目经费16万),2009年立项,结题

[7] 教育部留学回国人员科研启动基金项目,项目经费3.5万,2009年立项,结题

[8] 云南省教育厅科学研究重点项目,项目经费1万,2008年立项,结题

[9] 科研启动基金项目,项目经费2万,2008年立项,结题

[10] Fund for Science and Technology Innovation team in universities at Yunnan. 云南省高校应用数学创新团队


6. 代表性科研成果

1

王汉权(), 玻色-爱因斯坦凝聚中的量化涡旋及其动力学(Quantized vortex states and its dynamics in Bose-Einstein condensation), 科学出版社,20126月出版。

王汉权,成蓉华,微分方程数值方法有限差分法,科学出版社,20206月出版。

2已经发表的研究论文

[1] Weizhu Bao, Hanquan Wang and Peter A. Markowich, Ground, symmetric and central vortex states in rotating Bose-Einstein condensates , Communications in Mathematical Science, Vol. 3, No. 1, pp. 57-88, 2005. 2012年影响因子 1.589

[2] Hanquan Wang, Numerical studies on the split-step finite difference method for nonlinear Schrodinger equations, Applied Mathematics and Computation, Vol. 170, pp. 17-35, 2005. 2016年影响因子 1.345

[3] Weizhu Bao and Hanquan Wang, An efficient and spectrally accurate numerical method for computing dynamics of rotating Bose-Einstein condensates, Journal of Computational Physics, Vol. 217, No. 2, pp. 612-626, 2006. 2009影响因子 2.369

[4] Hanquan Wang, A time-splitting spectral method for coupled Gross-Pitaevskii equations with applications to the dynamics of rotating Bose-Einstein condensates, Journal of Computational and Applied Mathematics, Vol. 205, No. 1, pp. 88-104, 2007. 2009影响因子 1.292

[5] Hanquan Wang, A time-splitting spectral method for computing the dynamics of spinor F=1 Bose-Einstein condensates, International Journal of Computer Mathematics, Volume 84(2007), No. 6, pp. 925–944. 2009影响因子 0.546

[6] Weizhu Bao and Hanquan Wang, A mass conservative and energy diminishing numerical scheme for computing ground state of spin-1 Bose-Einstein condensates, SIAM Journal of Numerical Analysis, Volume 45(2007) Issue 5 , pp. 2177-2200. 2009影响因子 1.84

[7] Hanquan WangNumerical simulation on stationary states for rotating two-component Bose-Einstein condensatesJournal of Scientific Computing, Volume 38(2009), Number 2, pp.149-163. 2009影响因子 1.707

[8] Hanquan Wang, An efficient ChebyshevTau spectral method for GinzburgLandauSchrodinger equations,  Computer Physics CommunicationsVolume  181 (2010) pp. 325340.  2011年影响因子 3.2680

[9] Weizhu Bao, Yongyong Cai and  Hanquan Wang, Efficient numerical methods for computing ground states and dynamics of dipolar Bose-Einstein condensates, Journal of Computational Physics , Volume 2292010, Issue 20, pp.78747892.  2011影响因子 2.31

[10] Hanquan Wang, and Weibiao Xu, An efficient numerical method for simulating the dynamics of coupling Bose–Einstein condensates in optical resonators, Computer Physics Communications, Volume 182 (2011) pp.706718. 2011年影响因子 3.2680

[11] Hanquan Wang and Lina YantiAn Efficient Numerical Method for the Quintic Complex Swift-Hohenberg EquationNumerical Mathematics: Theory, Methods and Applications Volume 4 (2011), No. 2, pp. 237-254. 2011影响因子 0.692

[12] Hanquan Wang An efficient numerical method for computing dynamics of spin F=2 Bose-Einstein condensates, Journal of Computational Physics, Volume 230(2011), Issue 15, pp. 61556168. 2011年影响因子 2.31

[13] Degang Zhao, Hanquan Wang and Yang Xiang, Asymptotic behaviors of the stress fields in the vicinity of dislocations and dislocation segments,Philosophical Magazine,Volume 92 , pp. 2351-2374, 2012. 2011年影响因子 1.510

[14] Shu-Wei Song, Deng-Shan Wang, Hanquan Wang and W. M. Liu, Generation of ring dark solitons by phase engineering and their oscillations in spin-1 Bose-Einstein condensates, Physical Review A, Volume 85, article no. 063617, 2012.  2011影响因子 2.818

[15] L. Wen, Q. Sun, H. Q. Wang, A. C. Ji, and W. M. Liu, Ground state of spin-1 Bose-Einstein condensates with spin-orbit coupling in a Zeeman field, Physical Review A, Volume 86, article no. 043602, 2012. 2011影响因子 2.818

[16] Hanquan Wang and Yang Xiang, An adaptive level set method based on two-level uniform meshes and its application to dislocation dynamics,International Journal for Numerical Methods in Engineering, Volume 94, pp.573-597, 2013.  2011影响因子2.009

[17] Yongyong Cai and Hanquan Wang, Analysis and computation for ground state solutions of Bose-Fermi mixtures at zero temperature, SIAM Journal on Applied Mathematics,Volume 73(2),pp. 757–779 2013.

[18] Shu-Wei Song, Yi-Cai Zhang, Lin Wen and Hanquan Wang, Spin-orbit coupling induced displacement and hidden spin textures in spin-1 Bose–Einstein condensatesJ Phys. B: At. Mol. Opt. Phys., Volume 46, 145304 1-10(2013).

[19] Wei Jiang,Hanquan Wang(通信作者),and Xiang-gui Li, A numerical study on ground state and dynamics of atomic-molecular Bose-Einstein condensates, Computer Physics CommunicationsVolume 184, Issue 11, November 2013, Pages 2396-2407.  2011年影响因子 3.2680.

[20] Wei Jiang, Weizhu Bao, Qinglin Tang,and Hanquan WangA variational-difference numerical method for designing progressive-addition lensesComputer-Aided Design,Volume 48, Pages 17-27, March 2014.

[21] Hanquan WangA projection gradient method for computing ground state of spin-2 Bose–Einstein condensatesJournal of Computational Physics, Volume 274, 1 October 2014,Pages 473-488. 2011年影响因子 2.31

[22] Yichao Zhu, Hanquan Wang, Xiaohong Zhu, and Yang Xiang, A continuum model for dislocation dynamics incorporating Frank-Read sources and Hall-Petch relation in two dimensions,International Journal of Plasticity, Volume 60,September 2014, Pages 19-39.  五年影响因子 5.982


[23] Hanquan Wang and Zhiguo Xu, Projection gradient method for energy functional minimization with a constraint and its application to computing the ground state of spin-orbit-coupled Bose-Einstein condensates, Computer Physics Communications,Volume 185, Issue 11, November 2014, Pages 2803-2808.  2011年影响因子 3.2680

[24] Hanquan Wang, Yong Zhang, Xiu Ma, Jun Qiu, and Yan Liang, An efficient implementation of fourth-order compact finite difference scheme for Poisson equation with Dirichlet boundary conditions, Computers and Mathematics with Applications 71 (2016) 1843–1860.

[25] Jing Bai, Hanquan Wang, Qijie Wang, Debao Zhou, Khai Q. Le, and Bo Wang, Coherent pulse progression of mid-infrared quantum-cascade lasers under group-velocity dispersion and Self-Phase modulation, IEEE Journal of Quantum Electronics Vol. 52, No. 9, September 2016, 2300106.

[26] Hanquan Wang, Xiu Ma, Junliang Lu, Wen Gao, An efficient time-splitting compact finite difference method for Gross–Pitaevskii equation, Applied Mathematics and Computation 297 (2017) 131–144.

27Hanquan Wang, A splitting compact finite difference method for computing the dynamics of dipolar Bose-Einstein condensate, International Journal of computer mathematics, Volume 94, 2017 - Issue 10Pages 2027-2040.

28Tingchun Wang, Jiaping Jiang, Hanquan Wang, Weiwei Xu, An efficient and conservative compact finite difference scheme for the coupled Gross–Pitaevskii equations describing spin-1 Bose–Einstein condensate, Applied Mathematics and Computation, 323 (2018) 164–181.

[29] Hanquan Wang, Zhengguo Liang and, Ronghua LiuA splitting Chebyshev collocation method for Schrodinger-Poisson systemComputational and Applied MathematicsSeptember 2018, Volume 37, Issue 4, pp 5034–5057.

[30] J. Bai, H. Wang, J. Zhang and F. Liu, A comparative study of effects of group-velocity dispersion on mid-infrared quantum-cascade lasers with Fabry-Perot and ring cavities. Journal of Nanophotonics, 12(2), 026003 (2018).

[31] Yongjun Yuan, Zhiguo Xu, Qinglin Tang and Hanquan Wang*,A numerical study on ground states of spin-1 Bose-Einstein condensates with spin-orbit-coupling, East Asian Journal on Applied Mathematics, Vol. 8, No. 3, pp. 598-610, August 2018.

[32]Hanquan Wang, Ronghua Cheng and Xinmin Wu, A splitting Fourier pseudospectral method for Vlasov–Poisson–Fokker–Planck system, Computers & Mathematics with Applications, 79(2020), 1742-1758.

[33] Ronghua Cheng, Liping Wu, Chunping Pang and Hanquan Wang*, A Fourier collocation method for Schrodinger-Poisson system with perfectly matched layerCommunications in Mathematical Sciences20(2022), 523-542.

[34] Ronghua Cheng, Lihong Zhang and Hanquan Wang*,A collocation-based spectral element method for computing nonlinear optical waveguide, International Journal of Computer Mathematics, 100(2023), 591-614.

(3) 科研获奖:

云南省第十五批中青年学术带头人后备人才

教育部2013年度新世纪优秀人才(201394日教育部网上公示)

2014731日,获得云南省有突出贡献优秀专业技术人才称号, 三等奖

201710月,获得云南省自然科学奖”, 三等奖

201711月,获得云南省中青年学术带头人称号

7. 人才培养

担任博士生导师, 截至2022.12,指导在读博士5名。

截至2022.12,共招收全日制硕士研究生23,已毕业并获得学位16, 7人按学制在读。



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