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个人简介Personal Profile
高国营,副教授,博士生导师,博士毕业于华中科技大学凝聚态物理专业。主要从事自旋电子学与热电子学的研究,以第一/通讯作者在Adv. Funct. Mater., Mater. Today Phys., Phys. Rev. B和Appl. Phys. Lett.等刊物发表论文90多篇(包括ESI高被引,编辑推荐和期刊亮点、热点、封面),被包括Science和Phys. Rev. Lett.等论文引用4300多次,单篇被引用200次以上的论文5篇。担任Scientific Reports编委,Adv. Mater./Funct. Mater./Sci.和Nano Lett.等多个期刊的审稿人。曾获校研究生科技十佳、省优秀博士学位论文、校华中学者和中国高被引学者(2020,2023,2024)等称号。主持3项国家自然科学基金、1项教育部博士点基金和2项省自然科学基金。国家自然科学基金(面上、青年、地区)同行评议专家和教育部博士学位论文评审专家。指导博士毕业生9名,硕士毕业生9名,就职于重庆邮电大学、太原理工大学、青海大学、西安石油大学、海康威视和长江存储等高校与企业。
个人主页:http://faculty.hust.edu.cn/gaoguoying/zh_CN/index.htm
办公室:逸夫科技楼南412;邮箱:guoying_gao@mail.hust.edu.cn
研究方向:
1. 低维磁性和电子态的调控:电场、载流子掺杂、应变和异质结构等对磁各向异性、磁转变温度、自旋极化(磁性半金属、自旋无能隙半导体、双极磁性半导体)、谷极化和反常(谷)霍尔效应等的调控。多个理论预测被实验验证。
2. 低维自旋输运:磁隧道结和多铁隧道结的输运性质,包括隧穿磁电阻、隧穿电致电阻、自旋过滤效应、自旋二极管效应和自旋塞贝克效应等。
3. 热电输运:能带工程和低维结构等对电子和声子热输运性质的调控。
代表作:
(27) Y. Liu, L. Zhang, Z. Xu, S. Fan, and G. Gao∗, “Room-temperature bipolar ferrovalley semiconductors and anomalous valley Hall effect in Janus CeClI and CeBrI”, Mater. Today Phys. 55, 101743 (2025).
(26) Y. Liu, L. Zhang, X. Wu, and G. Gao∗, “Magnetic phase transition, enhanced magnetic anisotropy, and anomalous Hall effect in bilayer FeCl2 with different stacking orders”, Appl. Phys. Lett. 126, 162404 (2025).
(25) Z. Xu C. Wang, and G. Gao∗, “Janus Rashba semiconductor of RbKNaBi: High thermoelectric performance and ultralow lattice thermal conductivity”, Appl. Phys. Lett. 126, 162104 (2025).
(24) Z. Xu and G. Gao∗, “Enhanced thermoelectric performance of Janus Sn2PAs monolayer compared with its parents of SnP and SnAs”, 2D Mater. 12, 025024 (2025).
(23) L. Zhang, Y. Liu, M. Wu, and G. Gao∗, “Electric-field- and stacking-tuned antiferromagnetic FeClF bilayer: The coexistence of bipolar magnetic semiconductor and anomalous valley Hall effect”, Adv. Funct. Mater. 35, 2417857 (2025). (Front Cover)
(22) Y. Feng, J. Han, K. Zhang, X. Lin, G. Gao∗, Q. Yang*, and S. Meng*, “van der Waals multiferroic tunnel junctions based on sliding multiferroic layered VSi2N4”, Phys. Rev. B 109, 085433 (2024). (ESI)
(21) Z. Xu, Q. Xia, L. Zhang, and G. Gao∗, “van der Waals p-n heterostructure GaSe/SnS2: high thermoelectric figure of merit and strong anisotropy”, Nanoscale 16, 2513 (2024).
(20) L. Zhang, Y. Zhao, Y. Liu, and G. Gao∗, “High spin polarization, large perpendicular magnetic anisotropy and room-temperature ferromagnetism by biaxial strain and carrier doping in Janus MnSeTe and MnSTe”, Nanoscale 15, 18910 (2023).
(19) L. Zhang, Y. Liu, Z. Xu, and G. Gao∗, “Electronic phase transition, perpendicular magnetic anisotropy and high Curie temperature in Janus FeClF”, 2D Mater. 10, 045005 (2023).
(18) Y. Liu, L. Zhang, X. Wu, and G. Gao∗, “Enhanced ferromagnetism, magnetic anisotropy, and spin polarization in Janus CrSeTe via strain and doping”, Appl. Phys. Lett. 123, 192407 (2023).
(17) L. Hu, J. Han, and G. Gao∗, “Layer- and barrier-dependent spin filtering effect and high tunnel magnetoresistance in FeCl2 based van der Waals junctions”, Appl. Phys. Lett. 123, 052401 (2023).
(16) L. Hu, X. Wu, Y. Feng, Y. Liu, Z. Xu, and G. Gao∗, “Spin filtering effect, thermal spin diode effect and high tunneling magnetoresistance in the Au/GdI2/Au van der Waals junction”, Nanoscale 14, 7891 (2022).
(15) Y. Feng, Z. Wang, X. Zuo, and G. Gao∗, Electronic phase transition, spin filtering effect and spin Seebeck effect in 2D high-spin-polarized VSi2X4 (X=N, P, As), Appl. Phys. Lett. 120, 092405 (2022). (Editor’s Pick)
(14) Y. Feng, N. Liu, and G. Gao*, “Spin transport properties in Dirac spin gapless semiconductors Cr2X3 with high Curie temperature and large magnetic anisotropic energy”, Appl. Phys. Lett. 118, 112407 (2021).
(13) Y. Feng, X. Wu, and G. Gao∗, “High tunnel magnetoresistance based on 2D Dirac spin gapless semiconductor VCl3”, Appl. Phys. Lett. 116, 022402 (2020).
(12) C. Wang, G. Ding, X. Wu, S. Wei, and G. Gao∗, “Electron and phonon transport properties of layered Bi2O2Se and Bi2O2Te from first-principles calculations”, New J. Phys. 20, 123014 (2018).
(11) Y. Feng, X. Wu, J. Han, and G. Gao∗, “Robust half-metallicities and perfect spin transport properties in 2D transition metal dichlorides”, J. Mater. Chem. C 6, 4087 (2018). (被引85+次,被实验验证)
(10) J. Han and G. Gao∗, “Large tunnel magnetoresistance and temperature-driven spin filtering effect based on the compensated ferrimagnetic spin gapless semiconductor Ti2MnAl”, Appl. Phys. Lett. 113, 102402 (2018).
(9) J. Han, Y. Feng, K. Yao, and G.Y. Gao∗, “Spin transport properties based on spin gapless semiconductor CoFeMnSi”, Appl. Phys. Lett. 111, 132402 (2017).
(8) G. Ding, J. Chen, K. Yao, and G. Gao∗, “Enhanced thermoelectric properties of layered ZrS2 by orbital engineering”, New J. Phys. 19, 073036 ( 2017).
(7) G. Ding, J. Carrete, W. Li, G.Y. Gao∗, and K. Yao, “Ultralow lattice thermal conductivity in topological insulator TlBiSe2”, Appl. Phys. Lett. 108, 233902 (2016).
(6) G. Gao∗, G. Ding, J. Li, M. Wu, K. Yao, and M. Qian, “Monolayer MXenes: Promising half-metals and spin gapless semiconductors”, Nanoscale 8, 8986 (2016). (ESI, 被引410+次,被实验验证)
(5) G.Y. Gao∗ and K. L. Yao∗, “Surface half-metallicity of CrS thin films and perfect spin filtering and spin diode effects of CrS/ZnSe heterostructure”, Appl. Phys. Lett. 105, 182405 (2014).
(4) G.Y. Gao∗ and K.-L. Yao∗, “Antiferromagnetic half-metals, gapless half-metals, and spin gapless semiconductors: The D03-type Heusler alloys”, Appl. Phys. Lett. 103, 232409 (2013) (被引160+次,被实验验证)
(3) G. Y. Gao∗, L. Hu, K. L. Yao, B. Luo, and N. Liu, “Large half-metallic gaps in the quaternary Heusler alloys CoFeCrZ (Z=Al, Ga, Si, Ge): A first-principles study”, J. Alloys Compd. 551, 539 (2013). (ESI, 被引260+次, 被实验验证)
(2) G.Y. Gao∗ and K. L. Yao∗, “Half-metallic sp-electron ferromagnets in rock-salt structure: The case of SrC and BaC”, Appl. Phys. Lett. 91, 082512 (2007). (被引100+次)
(1) G.Y. Gao∗, K. L. Yao∗, E. Sasioglu∗, L. M. Sandratskii, Z. L. Liu, and J. L. Jiang, “Half-metallic ferromagnetism in zinc-blende CaC, SrC, and BaC from first-principles”, Phys. Rev. B 75, 174442 (2007). (被引320+次)
讲授课程:
大学物理(一、二),物理实验(一、二),凝聚态物理前沿。
教研论文:
张龙,高国营*, “范德瓦尔斯气体的状态方程与多方过程”, 物理与工程 34, 16 (2024)。