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杜宗正
副研究员
duzz@sustech.edu.cn


本人的研究方向为凝聚态理论,主要关注二维材料,拓扑材料, 磁性以及超导体系中的量子输运现象。目前的主要的研究兴趣包含:非线性响应,量子几何效应,关联体系中的量子输运。

 

研究领域

凝聚态理论,量子输运理论,量子磁性理论

 

教育背景

2009.09-2016.12: 博士,理论物理,南京大学物理学院

2005.09-2009.06:  学士,理论物理,延边大学物理系 

 

工作经历

2022.09-至今:  副研究员,量子科学与工程研究院

2019.05-2022.09:  助理研究员,量子科学与工程研究院

2017.03-2019.03:   博士后, 南方科技大学物理系

 

论文及专利

*共同一作

[1] Yongcheng Deng, Xionghua Liu, Yiyuan Chen, Zongzheng Du*, Nai Jiang, Chao Shen, Enze Zhang, Houzhi Zheng, Hai-Zhou Lu, Kaiyou Wang. “All-electrical switching of a topological non-collinear antiferromagnet at room temperature” National Science Review, nwac154 (2022).

[2] S. Li, C. M. Wang, Z. Z. Du, F. Qin, Hai-Zhou Lu, and X. C. Xie, “3D quantum Hall effects and nonlinear Hall effect”, Perspective for npj Quantum Materials 6, 96 (2021).

[3] Z. Z. Du, Hai-Zhou Lu, and X. C. Xie, “Nonlinear Hall effects”, Perspective for Nature Reviews Physics 3, 744 (2021).

[4] Z. Z. Du, C. M. Wang, Hai-Peng Sun, Hai-Zhou Lu, and X. C. Xie, “Quantum theory of the nonlinear Hall effect”, Nature Communications 12, 5038 (2021).

[5] Fang Qin, Shuai Li, Z. Z. Du, C. M. Wang, Wenqing Zhang, Dapeng Yu, Hai-Zhou Lu, and X. C. Xie, “Theory for the charge-density-wave mechanism of 3D quantum Hall effect”, Phys. Rev. Lett. 125, 206601 (2020).

[6] Z. Z. Du, C. M. Wang, Shuai Li, Hai-Zhou Lu, and X. C. Xie, “Disorder-induced nonlinear Hall effect with time-reversal symmetry”, Nature Communications 10 (1), 3047 (2019).

[7] Z. Z. Du, C. M. Wang, Hai-Zhou Lu, and X. C. Xie, “Band Signatures for Strong Nonlinear Hall Effect in Bilayer WTe2”, Phys. Rev. Lett. 121, 266601 (2018).

[8] Qiong Ma, Su-Yang Xu, Huitao Shen, David MacNeill, Valla Fatemi, Tay-Rong Chang, Andrés M. Mier Valdivia, Sanfeng Wu, Zongzheng Du, Chuang-Han Hsu, Shiang Fang, Quinn D. Gibson, Kenji Watanabe, Takashi Taniguchi, Robert J. Cava, Efthimios Kaxiras, Hai-Zhou Lu, Hsin Lin, Liang Fu, Nuh Gedik, and Pablo Jarillo-Herrero, “Observation of the nonlinear Hall effect under time-reversal-symmetric conditions”, Nature 565 (7739), 337 (2018).

[9] Xingshuai He, Haibo Gan, Zongzheng Du*, Bicong Ye, Liang Zhou, Yuan Tian, Shaozhi Deng, Guoping Guo, Haizhou Lu, Fei Liu, and Hongtao He, “Magnetoresistance Anomaly in Topological Kondo Insulator SmB6 Nanowires with Strong Surface Magnetism”, Advanced Science 5, 1700753 (2018).

[10] Xin Dai, Z. Z. Du*, and Hai-Zhou Lu, “Negative Magnetoresistance without Chiral Anomaly in Topological Insulators”, Physical Review Lett. 119, 166601 (2017).

[11] Cheng-Long Zhang,Su-Yang Xu, C. M. Wang, Ziquan Lin, Z. Z. Du, Cheng Guo, Chi-Cheng Lee, Hong Lu, Yiyang Feng, Shin-Ming Huang, Guoqing Chang, Chuang-Han Hsu, Haiwen Liu, Hsin Lin, Liang Li, Chi Zhang, Jinglei Zhang, Xin-Cheng Xie, Titus Neupert, M. Zahid Hasan, Hai-Zhou Lu, JunfengWang, and Shuang Jia, “Magnetic-tunnelling-induced Weyl node annihilation in TaP”, Nature Physics 13, 979–986 (2017).

[12] Z. Z. Du, H. M. Liu, Y. L. Xie, Q. H. Wang, and J.-M. Liu, “Magnetic excitations in quasi-one dimensional helimagnets: Magnon decays and influence of the inter-chain interactions”, Physical Review B 94.134416 (2016).

[13] Z. Z. Du, H. M. Liu, Y. L. Xie, Q. H. Wang, and J.-M. Liu, “Spin Casimir effect in noncollinear quantum antiferromagnets: Torque equilibrium spin wave approach”, Physical Review B 92, 214409. (2015).

 

完整发布文章列表可见本人Google Scholar 账号:

https://scholar.google.com/citations?user=gI2ZjEcAAAAJ&hl=zh-CN&authuser=1