师资
邓可,南方科技大学量子科学与工程研究院助理研究员。邓可博士于2013年取得西安交通大学应用物理学学士学位;2019年在清华大学物理系获得物理学博士学位;2015-2017年年获美国劳伦斯伯克利国家实验室ALS Doctoral Fellowship,在美国加州伯克利国家实验室先进光源同步辐射中心进行科学研究,开展基于同步辐射光源等大科学装置队量子材料电子结构的研究;2019年7月加入南方科技大学量子科学与工程研究院。邓可博士目前的研究兴趣主要集中在利用以角分辨光电子能谱Angle-resolved photoemission spectroscopy, ARPES)为主的谱学技术研究拓扑量子材料,低维材料和强关联电子材料等的新奇电子结构,进而理解并操控这些系统中丰富的物相和奇特的响应行为。此外,结合单晶生长和分子束外延(MBE)技术,精确定量地研究不同厚度、不同维度下物质的电子结构的演化和调控也是他的一个关注重点。
研究领域:
低维、拓扑量子材料与异质结系统的电子结构,电子盐化合物,量子物态调控,分子束外延,角分辨光电子能谱 (ARPES),X射线谱学技术等
教育背景
2013.09-2019.07 博士(物理学) 清华大学
2016.01-2017.10 访问学者 美国劳伦斯伯克利国家实验室 先进光源
2009.09-2013.07 学士(应用物理学) 西安交通大学
工作经历
2019.07—现在 助理研究员,南方科技大学量子科学与工程研究院
2016.01-2017.10 Research Scholar 美国劳伦斯伯克利国家实验室 先进光源
荣誉与奖项
2019清华大学-吴有训提名奖
2019清华大学-任之恭奖
2018清华大学综合一等奖学金
2015 & 2016 美国劳伦斯伯克利国家实验室先进光源 ALS Doctoral Fellowship
2013 西安交通大学优秀毕业生
学术兼职
2022-2024 Applied Physics Letters 顾问编委
2022-2024 Symmetry 主题编辑(Topic Editor)
主持与参加科研项目
1. 国家自然科学基金,青年基金,12004159,2021-01至2023-12,24万,主持
2. 广东省自然科学基金,面上项目,2022A1515011915,2022-01至2024-12,10万,主持
3. 广东省区域联合基金,青年项目,2019A1515110712,2020-01至2022-12,10万,主持
4. 深圳市科技创新人才培养项目,博士启动,RCBS20210706092218039, 2022-04至2024-04,30万,主持;
5. 国家自然科学基金,面上项目,12074163,2021-01至2024-12,62万,参加
论文及专利(按时间倒序排列)
[1] N. Lu, Z. Zhang, Y. Wang, H.-B. Li, S. Qiao, B. Zhao, Q. He, S. Lu, C. Li, Y. Wu, M. Zhu, X. Lyu, X. Chen, Z. Li, M. Wang, J. Zhang, S. C. Tsang, J. Guo, S. Yang, J. Zhang, K. Deng, D. Zhang, J. Ma, J. Ren, Y. Wu, J. Zhu, S. Zhou, Y. Tokura, C.-W. Nan, J. Wu, P. Yu, Enhanced low-temperature proton conductivity in hydrogen-intercalated brownmillerite oxide. Nature Energy, 2022: 1-9.
[2] Z. Wang, Z. Hao, Y. Yu, Y. Wang, S. Kumar, X. Xie, M. Tong, K. Deng, Y.-J. Hao, X.-M. Ma, K. Zhang, C. Liu, M. Ma, J. Mei, G. Wang, E. F. Schwier, K. Shimada, F. Xu, C. Liu, W. Huang, J. Wang, T. Jiang, C. Chen, Fermi Velocity Reduction of Dirac Fermions around the Brillouin Zone Center in In2Se3–Bilayer Graphene Heterostructures. Advanced Materials, 2021, 33(17): 2007503.
[3] H. Zhang, S. Wang, E. Wang, X. Lu, Q. Li, C. Bao, K. Deng, H. Zhang, W. Yao, G. Chen, A. V. Fedorov, J. D. Denlinger, K. Watanabe, T. Taniguchi, G. Zhang, S. Zhou, Experimental evidence of plasmarons and effective fine structure constant in electron-doped graphene/h-BN heterostructure. npj Quantum Materials, 2021, 6(1): 83.
[4] C. Bao, H. Zhang, Q. Li, S. Zhou, H. Zhang, K. Deng, K. Zhang, L. Luo, W. Yao, C. Chen, J. Avila, M. C. Asensio, Y. Wu, S. Zhou, Spatially-resolved electronic structure of stripe domains in IrTe2 through electronic structure microscopy, Communications Physics 4.1 (2021): 229 (2021).
[5] Z. Hao, W. Chen, Y. Wang, J. Li, X.-M. Ma, Y.-J. Hao, R. Lu, Z. Shen, Z. Jiang, W. Liu, Q. Jiang, Y. Yang, X. Lei, L. Wang, Y. Fu, L. Zhou, L. Huang, Z. Liu, M. Ye, D. Shen, J. Mei, H. He, C. Liu, K. Deng, C. Liu, Q. Liu, C. Chen, Multiple Dirac nodal lines in an in-plane anisotropic semimetal TaNiTe5, Phys. Rev. B.104.115158 (2021)
[6] X.-M. Ma*, Y. Zhao*, K. Zhang*, S. Kumar*, R. Lu, J. Li, Q. Yao, J. Shao, F. Hou, X. Wu, M. Zeng, Y.-J. Hao, Z. Hao, Y. Wang, X.-R. Liu, H. Shen, H. Sun, J. Mei, K. Miyamoto, T. Okuda, M. Arita, E. F. Schwier, K. Shimada, K. Deng, C. Liu, J. Lin, Y. Zhao, C. Chen, Q. Liu, Ch. Liu, Realization of a tunable surface Dirac gap in Sb-doped MnBi2Te4, Physical Review B 103, L121112 (2021)
[7] X. Li*, K. Deng*, B. Fu*, Y. Li*, D.-S. Ma, JF. Han, J. Zhou, SY. Zhou, Y. Yao, Type-III Weyl semimetals: (TaSe4)2I, Physical Review B 103, L081402 (2021) (Letter, Editor's Suggestion)
[8] R. Lu*, H. Sun*, S. Kumar*, Y. Wang*, M. Gu, M. Zeng, Y.-J. Hao, J. Li, J. Shao, X.-M. Ma, Z. Hao, K. Zhang, W. Mansuer, J. Mei, Y. Zhao, C. Liu, K. Deng, W. Huang, B. Shen, K. Shimada, E.F. Schwier, Ch. Liu, Q. Liu, C. Chen, Half-Magnetic Topological Insulator with Magnetization-Induced Dirac Gap at a Selected Surface, Physical Review X 11, 011039 (2021)
[9] K. Zhang*, M. Wang*, X. Zhou, Y. Wang, S. Shen, K. Deng, H. Peng, J. Li, X. Lai, L. Zhang, Y. Wu, W. Duan, P. Yu, S. Zhou, Growth of large scale PtTe, PtTe2 and PtSe2 films on a wide range of substrates, Nano Research (2020) https://doi.org/10.1007/s12274-020-2942-2.
[10] Y. Zhang*, K. Deng*, X. Zhang, M. Wang, Y. Wang, C. Liu, J.-W. Mei, S. Kumar, E.F. Schwier, K. Shimada, C. Chen, B. Shen, In-plane antiferromagnetic moments and magnetic polaron in the axion topological insulator candidate EuIn2As2, Physical Review B 101, 205126 (2020).
[11] K. Deng*, M. Yan*, C. Yu, J. Li, X. Zhou, K. Zhang, Y. Zhao, K. Miyamoto, T. Okuda, W. Duan, Y. Wu, X. Zhong, S. Zhou, Crossover from 2D metal to 3D Dirac semimetal in metallic PtTe2 films with local Rashba effect, Science Bulletin 64 (15): 1044-1048 (2019) (cover article)
[12] J. Ma*, K. Deng*, L. Zheng*, S. Wu, Z. Liu, S. Zhou, D. Sun, Experimental Progress on Layered Topological Semimetals, 2D Materials 6(3): 032001 (2019)
[13] K. Zhang, X. Liu, H. Zhang, K. Deng, M. Yan, W. Yao, M. Zheng, E. F. Schwier, K. Shimada, J. Denlinger, Y. Wu, W. Duan, S. Zhou, Evidence for a Quasi-One-Dimensional Charge Density Wave in CuTe by Angle-Resolved Photoemission Spectroscopy, Physical Review Letters 121. 206402 (2018)
[14] K. Zhang, K. Deng, J. Li, H. Zhang, W. Yao, J. Denlinger, Y. Wu, W. Duan, S. Zhou, Widely tunable band gap in a multivalley semiconductor SnSe by potassium doping. Physical Review Materials 2(5): 054603(2018)
[15] H. Yu, M. Liao, W. Zhao, G. Liu, X. Zhou, Z. Wei, X. Xu, K. Liu, Z. Hu, K. Deng, S. Zhou, J. Shi, L. Gu, C. Shen, T. Zhang, L. Du, L. Xie, J. Zhu, W. Chen, R. Yang, D. Shi, G. Zhang, Wafer-scale growth and transfer of highly-oriented monolayer MoS2 continuous films, ACS Nano 11(12): 12001-12007 (2017)
[16] W. Yao, E. Wang, H. Huang, K. Deng, M. Yan, K. Zhang, K. Miyamoto, T. Okuda, L. Li, Y. Wang, H. Gao, C. Liu, W. Duan, S. Zhou, Direct observation of spin-layer locking by local Rashba effect in monolayer semiconducting PtSe2 film. Nature Communications 8: 14216(2017)
[17] M. Yan*, H. Huang*, K. Zhang*, E. Wang, W. Yao, K. Deng, G. Wan, H. Zhang, M. Arita, H. Yang, Z. Sun, H. Yao, Y. Wu, S. Fan, W. Duan, S. Zhou, Lorentz-violating type-II Dirac fermions in transition metal dichalcogenide PtTe2, Nature Communications 8:257(2017)
[18] P. Deng, Z. Xu, K. Deng, K. Zhang, Y. Wu, H. Zhang, S. Zhou, X. Chen, Revealing Fermi arcs and Weyl nodes in MoTe2 by quasiparticle interference mapping, Physical Review B 95, 245110 (2017)
[19] K. Zhang, C. Bao, Q. Gu, X. Ren, H. Zhang, K. Deng, Y. Wu, Y. Li, J. Feng, S. Zhou, Raman signatures of inversion symmetry breaking and structural phase transition in type-II Weyl semimetal MoTe2, Nature Communications 7: 13552(2017)
[20] K. Deng*, G. Wan*, P. Deng*, K. Zhang, S. Ding, E. Wang, M. Yan, H. Huang, H. Zhang, Z. Xu, J. Denlinger, A. Fedorov, H. Yang, W. Duan, H. Yao, Y. Wu, S. Fan, H. Zhang, X. Chen, S. Zhou, Experimental observation of topological Fermi arcs in type-II Weyl semimetal MoTe2, Nature Physics 12(12):1105-1110 (2016)
[21] E. Wang, X. Lu, S. Ding, W. Yao, M. Yan, G. Wan, K. Deng, S. Wang, G. Chen, L. Ma, J. Jung, A. V. Fedorov, Y. Zhang, G. Zhang, S. Zhou, Gaps induced by inversion symmetry breaking and second-generation Dirac cones in graphene/hexagonal boron nitride, Nature Physics 12:1111-1116 (2016)
[22] W. Yao, E. Wang, K. Deng, S. Yang, W. Wu, A. Fedorov, S-K Mo, E. Schwier, M. Zheng, Y. Kojima, H. Iwasawa, K. Shimada, K. Jiang, P. Yu, J. Li, S. Zhou, Monolayer charge-neutral graphene on platinum with extremely weak electron-phonon coupling, Physical Review B 92, 115421(2015)