个人简历
教育背景
2010.09-2013.07 中国 我校 工学博士 电子科学与技术
2004.09-2008.07 中国 天津大学 工学学士 光电子技术科学
工作经历
2013.07-2015.09 中国 清华大学物理系博士后
2015.10-2019.04 德国 不莱梅大学博士后
2019.05-2021.08 中国 北京计算科学研究中心和深圳京鲁计算科学应用研究院博士后
2021.09-现在 中国 我校电子信息与光电工程学院
主要研究领域是凝聚态计算物理和计算材料学,长期致力于包括自旋电子学、二维磁性体系和稀磁半导体等方面的研究。具体研究工作围绕包含磁性杂质的低维材料和体材料中电子自旋相关性质所展开,主要通过第一性原理计算并结合等效哈密顿量模型方法,深入探寻该类杂质局域磁矩的形成机制和稳定性与局部对称性的关系,以及局域磁矩与宿主材料中电子之间的相互作用,并通过这些研究找寻有效的外部调控手段,例如以电场或光激发来操控局域磁矩的方法。近年来,已经在Nature Communications、Nano Letters、ACS Nano等同行评审期刊上共发表29篇SCI论文。
科研项目/成果/获奖/专利
项目
“基于磁力理论的二维磁性调控机制研究项目” 校青年教师研究项目 (2022)
中德科学中心Mobility合作交流项目 参与 (2021-2023)
广东省基础与应用基础研究基金项目 参与 (2020-2022)
“Research Training Group - Quantum Mechanical Materials Modelling” 德国科学基金会DFG RTG 参与 (2017-2021)
“European Graphene Flagship” 欧盟委员会 参与 (2016-2018)
“Effects of the interfacial transition metal intercalation on the Dirac surface states of topological insulators” University of Bremen and the European Union FP7 COFUND 主持 (2015-2017)
“反钙钛矿结构中 Weyl 费米子的第一性原理研究” 中国博士后基金面上项目 主持 (2014-2015)
成果
“Hk4magnetism Calculation Platform V1.0” 软件著作权 (2020)
获奖
深圳市海外高层次人才孔雀计划C类 (2020)
MARIE CURIE Fellowship (BREMEN TRAC-COFUND)(2015)
论文/专著/教材
[1] B. Yang, B. Shao, J. Wang, Y. Li, C. Yam, S. Zhang, and B. Huang, Realization of Semiconducting Layered Multiferroic Heterojunctions via Asymmetrical Magnetoelectric Coupling, Phys. Rev. B 103, L201405 (2021).
[2] J. Wang, J. Niu, B. Shao, G. Yang, C. Lu, M. Li, Z. Zhou, X. Chuai, J. Chen, N. Lu, B. Huang, Y. Wang, L. Li, and M. Liu, A Tied Fermi Liquid to Luttinger Liquid Model for Nonlinear Transport in Conducting Polymers, Nat Commun 12, 1 (2021).
[3] S. Shen, B. Shao*, C. Wen, X. Yuan, J. Gao, Z. Nie, X. Luo, B. Huang, Y. Sun, S. Meng, and S. Yan*, Single-Water-Dipole-Layer-Driven Reversible Charge Order Transition in 1T-TaS2, Nano Lett. 20, 8854 (2020).
[4] N. Néel, J. Kröger, M. Schüler, B. Shao, T. O. Wehling, A. Kowalski, and G. Sangiovanni, Single-Co Kondo Effect in Atomic Cu Wires on Cu(111), Phys. Rev. Research 2, 023309 (2020).
[5] X. Wu, R. Wang, N. Liu, H. Zou, B. Shao, L. Shao, and C. Yam, Controlling the Emission Frequency of Graphene Nanoribbon Emitters Based on Spatially Excited Topological Boundary States, Phys. Chem. Chem. Phys. 22, 8277 (2020).
[6] Z. Qin, G. Qin, B. Shao, and X. Zuo, Rashba Spin Splitting and Perpendicular Magnetic Anisotropy of Gd-Adsorbed Zigzag Graphene Nanoribbon Modulated by Edge States under External Electric Fields, Phys. Rev. B 101, 014451 (2020).
[7] N. Néel, B. Shao, T. O. Wehling, and J. Kröger, Manipulation of the Two-Site Kondo Effect in Linear CoCu n CoCu m Clusters, J. Phys.: Condens. Matter 32, 055303 (2019).
[8] B. Shao, A. Eich, C. Sanders, A. S. Ngankeu, M. Bianchi, P. Hofmann, A. A. Khajetoorians, and T. O. Wehling, Pseudodoping of a Metallic Two-Dimensional Material by the Supporting Substrate, Nature Communications 10, 180 (2019).
[9] B. Shao, M. Schüler, G. Schönhoff, T. Frauenheim, G. Czycholl, and T. O. Wehling, Optically and Electrically Controllable Adatom Spin–Orbital Dynamics in Transition Metal Dichalcogenides, Nano Lett. 17, 6721 (2017).
[10] B. Liu, H. Fu, J. Guan, B. Shao, S. Meng, J. Guo, and W. Wang, An Iron-Porphyrin Complex with Large Easy-Axis Magnetic Anisotropy on Metal Substrate, ACS Nano 11, 11402 (2017).
[11] Z. Qin, G. Qin, B. Shao, and X. Zuo, Unconventional Magnetic Anisotropy in One-Dimensional Rashba System Realized by Adsorbing Gd Atom on Zigzag Graphene Nanoribbons, Nanoscale 9, 11657 (2017).
[12] M. Feng, B. Shao, X. W. Cao, and X. Zuo, Half-Metallicity in CuCr2S4 Film: A Density Functional Study, IEEE Transactions on Magnetics 52, 1 (2016).
[13] L. Zhou, J. Zhang, Z. Zhuo, L. Kou, W. Ma, B. Shao, A. Du, S. Meng, and T. Frauenheim, Novel Excitonic Solar Cells in Phosphorene–TiO2 Heterostructures with Extraordinary Charge Separation Efficiency, J. Phys. Chem. Lett. 7, 1880 (2016).
[14] Y. Lu, T. Zhou, B. Shao, X. Zuo, and M. Feng, Carrier-Dependent Magnetic Anisotropy of Gd-Adsorbed Graphene, AIP Advances 6, 055708 (2016).
[15] L. Zhou, W. Shi, Y. Sun, B. Shao, C. Felser, B. Yan, and T. Frauenheim, Two-Dimensional Rectangular Tantalum Carbide Halides TaCX (X = Cl, Br, I): Novel Large-Gap Quantum Spin Hall Insulators, 2D Mater. 3, 035018 (2016).
[16] L. Zhou, B. Shao, W. Shi, Y. Sun, C. Felser, B. Yan, and T. Frauenheim, Prediction of the Quantum Spin Hall Effect in Monolayers of Transition-Metal Carbides MC (M = Ti, Zr, Hf), 2D Mater. 3, 035022 (2016).
[17] Y.-F. He and B. Shao*, Electronic Structure and Magnetic Properties of an Iron- and Tantalum-Based Double Perovskite, Phys. Status Solidi B 252, 2723 (2015).
[18] X. Sui, C. Si, B. Shao, X. Zou, J. Wu, B.-L. Gu, and W. Duan, Tunable Magnetism in Transition-Metal-Decorated Phosphorene, J. Phys. Chem. C 119, 10059 (2015).
[19] B. Shao, W.-J. Shi, M. Feng, and X. Zuo, Large Perpendicular Magnetic Anisotropy of Single Co Atom on MgO Monolayer: A First-Principles Study, J. Appl. Phys. 117, 17B316 (2015).
[20] M. Feng, B. Shao, X. Cao, and X. Zuo, Dirac Cones in Transition Metal Doped Boron Nitride, J. Appl. Phys. 117, 17C118 (2015).
[21] B. Shao, M. Feng, and X. Zuo, Carrier-Dependent Magnetic Anisotropy of Cobalt Doped Titanium Dioxide, Sci. Rep. 4, (2014).
[22] Y.-F. Zhang, M. Feng, B. Shao, Y. Lu, H. Liu, and X. Zuo, Ab Initio Calculations on Magnetism Induced by Composite Defects in Magnesium Oxide, J. Appl. Phys. 115, 17A926 (2014).
[23] M. Feng, B. Shao, Y. Lu, and X. Zuo, Exchange Integrals in Magnetoelectric Hexagonal Ferrite (SrCo2Ti2Fe8O19): A Density Functional Study, J. Appl. Phys. 115, 17D908 (2014).
[24] B. Shao, Y. He, M. Feng, Y. Lu, and X. Zuo, Unexpected Magnetic Anisotropy Induced by Oxygen Vacancy in Anatase TiO2: A First-Principles Study, J. Appl. Phys. 115, 17A915 (2014).
[25] Y. Lu, M. Feng, B. Shao, and X. Zuo, Dirac Cones in Artificial Structures of 3d Transitional-Metals Doped Mg-Al Spinels, J. Appl. Phys. 115, 17E119 (2014).
[26] B. Shao, M. Feng, H. Liu, J. Wu, and X. Zuo, Ab Initio Study of Magnetic Anisotropy in Cobalt Doped Zinc Oxide with Electron-Filling, J. Appl. Phys. 113, 17C728 (2013).
[27] M. Feng, B. Shao, J. Wu, and X. Zuo, Ab Initio Study on Magnetic Anisotropy Change of SrCoxTixFe12−2xO19, J. Appl. Phys. 113, 17D909 (2013).
[28] B. Shao, H. Liu, J. Wu, and X. Zuo, Ab Initio Calculation of the Local Magnetic Moment in Titanium Doped Zinc Oxide with a Corrected-Band-Gap Scheme, J. Appl. Phys. 111, 07C301 (2012).
[29] B. Shao, H. Liu, and X. Zuo, Ab-Initio Calculation of Magnetic Anisotropy Energy of Iron-Gallium Alloy in Phase, IEEE Trans. Magn. 47, 2908 (2011).
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