王建峰 - 北京航空航天大学

个人简介

王建峰，博士，副教授。2010年本科毕业于兰州大学物理学院，2016年博士毕业于清华大学物理系（导师：段文晖院士）。2016年至2021年在北京计算科学研究中心做博士后研究，于2014年和2019年分别到美国宾州州立大学和犹他大学交流访问。主要从事计算凝聚态物理研究，致力于发展和应用第一性原理及有效模型方法，研究量子材料中的新奇电子性质和激发行为，并开发了拓扑不变量、等离激元、蒙特卡洛等计算程序。此前预言了易于实验观测的理想拓扑半金属材料和新型拓扑电子态；发现了拓扑材料中非传统等离激元，并建立不同类型等离激发的统一形式；揭示了低维异质/同质结构增强光电性能、实现电控磁的新机理。研究成果得到了国际同行的广泛关注，理论预言的一些性质被实验所观测和证实，并受邀撰写综述。迄今共发表SCI论文28篇，Web of Science引用总计500余次。以第一或通讯作者身份发表SCI论文14篇，其中包括3篇Phys. Rev. Lett.，1篇PNAS，1篇Nature Commun.，1篇Nano Lett.，5篇Phys. Rev. B；一篇PRL为ESI高被引论文，一篇Adv. Mater.为内封面文章。在国内外会议上作报告10余次，并担任Nat. Commun., Phys. Rev. Lett., Nano Lett.等国际一流期刊审稿人。教育经历 2010.9 -- 2016.7 清华大学物理系物理学博士研究生毕业理学博士学位 2006.9 -- 2010.7 兰州大学物理学大学本科毕业理学学士学位工作经历 2021.9 -- 至今北京航空航天大学物理学院副教授在职 2019.5 -- 2019.7 美国犹他大学访问学者 2016.9 -- 2021.9 北京计算科学研究中心博士后社会兼职担任PRL, Nat. Commun., Nano Lett., PRB, JPCC, Nanoscale等国际期刊审稿人

研究领域

主要从事凝聚态物理和材料计算的研究，致力于发展和应用第一性原理及有效模型方法，研究量子体系中的新奇电子性质和激发行为。研究领域包括：（1）拓扑物质中的新奇电子态（2）低维体系的光电、磁和铁电性质（3）量子材料的激子、等离激元等激发性质（4）半导体中的缺陷物理

近期论文

查看导师最新文章（温馨提示：请注意重名现象，建议点开原文通过作者单位确认）

J. Wang, X. Sui, W. Duan, F. Liu, and B. Huang, "Density-independent plasmons for terahertz-stable topological metamaterials", PNAS 118, e2023029118 (2021). J. Wang, X. Sui, S. Gao, W. Duan, F. Liu, and B. Huang, "Anomalous Dirac Plasmons in 1D Topological Electrides", Phys. Rev. Lett. 123, 206402 (2019). J. Wang, X. Sui, W. Shi, J. Pan, S. Zhang, F. Liu, S.-H. Wei, Q. Yan, and B. Huang, "Prediction of Ideal Topological Semimetals with Triply Degenerate Points in the NaCu3Te2 Family", Phys. Rev. Lett. 119, 256402 (2017). S. Zhang#, J. Wang#, S. Wen#, M. Jiang, H. Xiao, X. Ding, N. Wang, M. Li, X. Zu, S. Li, C. Yam, B. Huang, and L. Qiao, "Approaching Charge Separation Efficiency to Unity without Charge Recombination", Phys. Rev. Lett. 126, 176401 (2021). (共同一作) X. Dong#, J. Wang#, R. Zhang, W. Duan, B. Zhu, J. O. Sofo, and C.-X. Liu, "Electrically tunable multiple Dirac cones in thin films of the (LaO)2(SbSe2)2 family of materials", Nature Commun. 6, 8517 (2015). (共同一作) J. Wang, Y. Liu, K.-H. Jin, X. Sui, L. Zhang, W. Duan, F. Liu, and B. Huang, "Pseudo Dirac nodal sphere semimetal", Phys. Rev. B (Rapid Commun.) 98, 201112 (2018). X. Sui, J. Wang*, C. Yam, and B. Huang*, "Two-Dimensional Magnetic Anionic Electrons in Electrides: Generation and Manipulation", Nano Lett. 21, 3813 (2021). (共同通讯) Z. Wang*, Z. Hao, et al., J. Wang*, T. Jiang, and C. Chen*, "Fermi velocity reduction of Dirac fermions around the Brillouin zone center in In2Se3-bilayer graphene heterostructure", Adv. Mater. 33, 2007503 (2021). (Inside Front Cover) (共同通讯) J. Wang, J. Liu, Y. Xu, J. Wu, B.-L. Gu, and W. Duan, "Structural stability and topological surface states of SnTe (111) surface", Phys. Rev. B 89, 125308 (2014). S. Du#, J. Wang#, L. Kang, B. Huang, and W. Duan, "Giant enhancement of solid solubility in monolayer alloys by selective orbital coupling", Phys. Rev. B 101, 054201 (2020). (共同一作) L. Zhao#, J. Wang#, J. Liu#, Y. Xu, B.-L. Gu, Q.-K. Xue, and W. Duan, "Electronic analog of chiral metamaterial: Helicity-resolved filtering and focusing of Dirac fermions in thin films of topological materials", Phys. Rev. B (Rapid Commun.) 92, 041408 (2015). (Editors' suggestion) (共同一作) L. Zhao#, J. Wang#, B.-L. Gu, and W. Duan, "Tuning surface Dirac valleys by strain in topological crystalline insulators", Phys. Rev. B 91, 195320 (2015). (共同一作) X. Sui, J. Wang*, and W. Duan*, "Prediction of Stoner-Type Magnetism in Low-Dimensional Electrides", J. Phys. Chem. C 123, 5003 (2019). (共同通讯) J. Wang, N. Wang, H. Huang, and W. Duan, "Electronic properties of SnTe-class topological crystalline insulator materials", Chin. Phys. B 25, 117313 (2016). B. Cui, X. Zheng, J. Wang, D. Liu, S. Xie, and B. Huang, “Realization of Lieb lattice in covalent-organic frameworks with tunable topology and magnetism”, Nature Commun. 11, 66 (2020). J. Xu, J. Liu, B. Liu, J. Wang, and B. Huang, “Defect Engineering of Grain Boundaries in Lead-Free Halide Double Perovskites for Better Optoelectronic Performance”, Adv. Funct. Mater. 29, 1805870 (2019). Y. Li, Y. Liu, C. Wang, J. Wang, Y. Xu, and W. Duan, “Electrically tunable valleytronics in quantum anomalous Hall insulating transition metal trihalides”, Phys. Rev. B (Rapid Commun.) 98, 201407 (2018). J. Xu, J. Liu, J. Wang, B. Liu, and B. Huang, “Prediction of Novel p-Type Transparent Conductors in Layered Double Perovskites: A First-Principles Study”, Adv. Funct. Mater. 28, 1800332 (2018). X. Sui, C. Wang, J. Kim, J. Wang, S. H. Rhim, W. Duan, and N. Kioussis, “Giant enhancement of the intrinsic spin Hall conductivity in β-tungsten via substitutional doping”, Phys. Rev. B (Rapid Commun.) 96, 241105 (2017). X. Sui, T. Hu, J. Wang, B.-L. Gu, W. Duan, and M. Miao, “Voltage-controllable colossal magnetocrystalline anisotropy in single-layer transition metal dichalcogenides”, Phys. Rev. B (Rapid Commun.) 96, 041410 (2017). X. Liu, C. Wang, J. Wang, H. Huang, B.-L. Gu, and W. Duan, “Finite-size effects and spin texture of hourglass fermions in KHgSb ?lms”, Phys. Rev. B 95, 235126 (2017). H. Huang, Y. Xu, J. Wang, and W. Duan, “Emerging topological states in quasi-two-dimensional materials”, WIREs Comput. Mol. Sci. 7, e1296 (2017). N. Wang, J. Wang, C. Si, B.-L. Gu, and W. Duan, “Defect energetics and magnetic properties of 3d-transition-metal-doped topological crystalline insulator SnTe”, Sci. China-Phys. Mech. Astron. 59, 680012 (2016). H. Wang, J. Wang, T. Wang, M. Li, L. Zhao, A. Vial, and W. Duan, “Plasmons of topological crystalline insulator SnTe with nanostructured patterns”, RSC Adv. 6, 56042 (2016). Z. Wang, J. Wang, Y. Zang, Q. Zhang, J.-A. Shi, T. Jiang, Y. Gong, C.-L. Song, S.-H. Ji, L.-L. Wang, L. Gu, K. He, W. Duan, X. Ma, X. Chen, and Q.-K. Xue, “Molecular Beam Epitaxy-Grown SnSe in the Rock-Salt Structure: An Artificial Topological Crystalline Insulator Material”, Adv. Mater. 27, 4150 (2015). C. Yan, J. Liu, Y. Zang, J. Wang, Z. Wang, P. Wang, Z.-D. Zhang, L. Wang, X. Ma, S. Ji, K. He, L. Fu, W. Duan, Q.-K. Xue, and X. Chen, “Experimental Observation of Dirac-like Surface States and Topological Phase Transition in Pb1?xSnxTe(111) Films”, Phys. Rev. Lett. 112, 186801 (2014).