赵海军

赵海军   博士/副教授

主要研究方向：磁性斯格明子、超导磁通等

联系方式：haijunzhao@seu.edu.cn

办公室：东南大学九龙湖校区田家炳北楼312

教育与工作经历：

2018/08-2018/11  美国Ames国家重点实验室访问学者

2018/04-至今      东南大学网站：www.cangchudai.com Copyright@2023 版权所有：太阳集团(1088vip-网站VIP认证)·百度百科   副教授

2014/04-2018/04    东南大学网站：www.cangchudai.com Copyright@2023 版权所有：太阳集团(1088vip-网站VIP认证)·百度百科      讲师

2012/06-2013/07    比利时安特卫普大学博士后

2007/09-2012/06        比利时安特卫普大学 博士   

2006/09-2007/09        比利时安特卫普大学 硕士

2002/10-2006/06        浙江大学物理系 学士

主持和参加的科研项目：

1.国家自然科学基金青年基金，涡旋低聚物的形成机理及其近晶流动态的研究，11704067，2011/01-2013/12，29万，已结题、主持；

2.江苏省自然科学青年基金，BK20150595，层状超导体中磁通涡旋的有序-无序相变及其非线性输运过程的研究，2016/01-2018/12，20万，已结题、主持;

3.国家重点研发计划，2018YFA0704300，基于FeSeTe涂层超导材料的下一代高场磁体关键技术及相关机理研究，2019/09-2024/08, 1625万，在研、参加；

4.国家自然科学基金面上项目，11674054，高分辨迁移率谱方法研究铁基超导体的多带效应及相关机理，2017/01-2020/12，67万，已结题、参加； 

5.中科院先导B，XDB25000000，高温超导应用的基础理论与前沿科学问题，2018/11-2023/12，125万，在研、参加； 

发表文章（#共同一作，*共同通讯）

[1]H. Zhao, W. Li, Y. Chen, C. Xu, B. Li, W. Luo, D. Qian, and Z. Shi, Transport Property of Multi-Band Topological Material PtBi₂ Studied by Maximum Entropy Mobility Spectrum Analysis (MEMSA), Sci Rep 11, 6249 (2021).

[2]T.-H. Kim, H. Zhao, P.-V. Ong, B. A. Jensen, B. Cui, A. H. King, L. Ke*, and L. Zhou*, Kinetics of Magnetic Skyrmion Crystal Formation from the Conical Phase, Nano Lett. 21, 5547 (2021).

[3]W.-C. Li, L.-X. Zhao, H.-J. Zhao*, G.-F. Chen, and Z.-X. Shi*, Maximum Entropy Mobility Spectrum Analysis for the Type-I Weyl Semimetal TaAs, Chinese Phys. B (2021).

[4]E. Gordon, V. V. Mkhitaryan, H. Zhao, Y. Lee, and L. Ke, Magnetic Interactions and Spin Excitations in van Der Waals Ferromagnet VI₃, J. Phys. D: Appl. Phys. 54, 464001 (2021).

[5]T.-H. Kim#, H. Zhao#, B. Xu, B. A. Jensen, A. H. King, M. J. Kramer, C. Nan, L. Ke, and L. Zhou, Mechanisms of Skyrmion and Skyrmion Crystal Formation from the Conical Phase, Nano Lett. 20, 4731 (2020).

[6]W. Zhou, X. Xing, H. Zhao, J. Feng, Y. Pan, N. Zhou, Y. Zhang, B. Qian, and Z. Shi, Anomalous Electron Doping Independent Two-Dimensional Superconductivity, New Journal of Physics 19, 073014 (2017).

[7]X. Xing, Z. Li, C. Xu, W. Zhou, X. Xu, B. Chen, H. Zhao, M. Xu, and Z. Shi, Synthesis and Transport Properties of 112-Type Iron Pnictide Superconductors Ca1-XCexFe1-YCoyAs2, Journal of Alloys and Compounds 721, 261 (2017).

[8]W. Wu, H. J. Zhao*, B. Li, and Z. X. Shi, Finite-Size and Shape Effects on Vortex Configurations in Superconducting Isosceles Right Triangles, Superconductor Science and Technology 30, 125004 (2017).

[9]H. J. Zhao, W. Wu, W. Zhou, Z. X. Shi, V. R. Misko, and F. M. Peeters, Reentrant Dynamics of Driven Pancake Vortices in Layered Superconductors, Phys. Rev. B 94, 024514 (2016).

[10]W. Zhou, X. Xing, W. Wu, H. Zhao*, and Z. Shi*, Second Magnetization Peak Effect, Vortex Dynamics, and Flux Pinning in 112-Type Superconductor Ca0.8La0.2Fe1−xCoxAs2, Scientific Reports 6, 22278 (2016).

[11]W. Wu, H. J. Zhao*, W. Zhou, and Z. X. Shi*, Equilibrium States of Pancake Vortices in Layered Superconductors: Coupling of Inter-Layer Ordering and in-Layer Ordering, Superconductor Science and Technology 29, 105007 (2016).

[12]X. Xing, W. Zhou, N. Zhou, F. Yuan, Y. Pan, H. Zhao, X. Xu, and Z. Shi, Anisotropic Ginzburg–Landau Scaling of H _c 2 and Transport Properties of 112-Type Ca _0.8 La _0.2 Fe _0.98 Co _0.02 As ₂ Single Crystal, Superconductor Science and Technology 29, 055005 (2016).

[13]H. J. Zhao, V. R. Misko, and F. M. Peeters, Dynamics of Self-Organized Driven Particles with Competing Range Interaction, Phys. Rev. E 88, 022914 (2013).

[14]H. J. Zhao, V. R. Misko, and F. M. Peeters, Vortex Configurations with Non-Monotonic Interaction, Physica C: Superconductivity 479, 130 (2012).

[15]H. J. Zhao, V. R. Misko, and F. M. Peeters, Analysis of Pattern Formation in Systems with Competing Range Interactions, New Journal of Physics 14, 063032 (2012).

[16]W. V. Pogosov, H. J. Zhao, V. R. Misko, and F. M. Peeters, Kink-Antikink Vortex Transfer in Periodic-plus-Random Pinning Potential: Theoretical Analysis and Numerical Experiments, Phys. Rev. B 81, 024513 (2010).

[17]V. R. Misko, H. J. Zhao, F. M. Peeters, V. Oboznov, S. V. Dubonos, and I. V. Grigorieva, Formation of Vortex Shells in Mesoscopic Superconducting Squares, Superconductor Science and Technology 22, 034001 (2009).

[18]W. V. Pogosov, V. R. Misko, H. J. Zhao, and F. M. Peeters, Collective Vortex Phases in Periodic plus Random Pinning Potential, Phys. Rev. B 79, 014504 (2009).

[19]H. J. Zhao, V. R. Misko, F. M. Peeters, V. Oboznov, S. V. Dubonos, and I. V. Grigorieva, Vortex States in Mesoscopic Superconducting Squares: Formation of Vortex Shells, Phys. Rev. B 78, 104517 (2008).

[20]H. J. Zhao, V. R. Misko, F. M. Peeters, S. Dubonos, V. Oboznov, and I. V. Grigorieva, Vortex Configurations in Mesoscopic Superconducting Triangles: Finite-Size and Shape Effects, Europhys. Lett. 83, 17008 (2008).