个人简介

何庆林，博士，教授，博士生导师，国家海外引才计划青年项目入选者，Vebleo协会会士。主持国家自然科学基金委面上项目1项、北京大学“仪器创制与关键技术研发”项目1项，以核心骨干身份参与国家重点研发计划共2项、中国科学院战略性先导科技专项（B类）1项。长期从事分子束外延、半导体、量子材料与量子计算研究，包括各类半导体、量子材料、拓扑材料、超导体、磁性材料，具有近20年的材料生长经验。研究方向涵盖凝聚态物理的多个前沿领域，包括材料外延、拓扑物理、量子效应，拓扑自旋电子学，拓扑超导，拓扑量子计算等。在国际主要学术杂志Nat. Mater.、Nat. Comm.、Nat. Elec.、PRL、Sci. Adv.、PNAS等上发表论文40余篇。负责人荣获2017 年《麻省理工科技评论》中国区“35 岁以下科技创新35 人”先锋者奖，入选2018年福布斯中国30岁以下精英榜、2026年Vebleo协会会士。

教育背景

2007.09－2011.06 中山大学物理学院，本科

2011.09－2015.01 香港科技大学物理系，博士

工作经历

2015.03－2018.04 美国加州大学洛杉矶分校电子工程系，博士后

2018.05－2025.07 北京大学物理学院量子材料科学中心，助理教授、研究员、博士生导师

2020.01－2025.07 北京大学轻元素量子材料交叉平台，研究员、博士生导师

2025.08－至今 东莞理工学院集成电路学院，教授、硕博导师

科学研究

（1）承担的研究项目

1. 国家海外引才计划青年项目，2018-2021，主持

2. 国家自然科学基金面上项目，2019-2022，主持

3. 科学技术部国家重点研发计划项目，2018-2023，参与

4. 中国科学院战略先导科技专项（B类），2018-2023，参与

5. 北京大学学科建设项目，2019-2022，主持

6. 科学技术部国家重点研发计划项目（青年项目），2020-2025，参与

7 北京大学仪器创制与关键技术研发，2020-2022，主持

8. 东莞理工学院人才启动项目，2025年-至今，主持

9. 广东省重点建设学科科研能力提升项目，2025年-至今，主持

10. 东莞理工学院重大项目，2026年-至今，主持

（2）发表的学术论文和著作

1. Y. Fu, Y. Huang, and Q. L. He*, “Non-reciprocal Coulomb drag between Chern insulators”, Nature Communications 16, 3058 (2025).

2. Y. Huang, Y. Fu, P. Zhang, K. L. Wang and Q. L. He*, “Inducing superconductivity in quantum anomalous Hall regime”, Journal of Physics: Condensed Matter 36 (2024) 37LT01.

3. H. Sun#, Y. Liu#, D. Huang, Y. Fu, Y. Huang, M. He, X. Luo, W. Song, Y. Liu, G. Yu, Q. L. He*, “Nonvolatile magnetization switching in a single-layer magnetic topological insulator”, Communications Physics 6, 222 (2023).

4. H. Sun, Y. Huang, M. He, Y. Fu, S. Zheng, B. Zhang, C. Wang*, Q. L. He*, “Chiral and helical states in selective-area epitaxial heterostructure”, Communications Physics 6, 204 (2023).

5. M. He, Y. Fu, Y. Huang, H. Sun, T. Guo, W. Lin, Y. Zhu, Y. Zhang, Y. Liu, G. Yu, Q. L. He*, “Intrinsic and extrinsic dopings in epitaxial films MnBi2Te4”, Journal of Physics: Condensed Matter 35 (2023) 295701.

6. M. He, Y. Huang, H. Sun, Y. Fu, P. Zhang, K. L. Wang, Q. L. He*, “Probing the percolation in the quantum anomalous Hall insulator”, New Journal of Physics 25, 033003 (2023).

7. M. He, Y. Huang, H. Sun, Y. Fu, P. Zhang, C. Zhao, K. L. Wang, G. Yu, and Q. L. He*, “Quantum anomalous Hall interferometer”, Journal of Applied Physics 133, 084401 (2023).

8. Y. Huang, H. Sun, M. He, Y. Fu, P. Zhang, K. L. Wang, Q. L. He*, “Bias-modulated switching in Chern insulator”, New Journal of Physics 24, 083036 (2022).

9. H. Sun, Y. Huang, P. Zhang, M. He, Y. Fu, K. L. Wang, Q. L. He*, “Topological transitions in the presence of random magnetic domains”, Communications Physics 5, 217 (2022).

10. Q. L. He*, “Stencil lithography for in-situ fabricating quantum devices”, Chinese Journal Vacuum Science and Technology, 2023, 43(3): 163-176.

11. Q. L. He*, T. L. Hughes, N. P. Armitage, Y. Tokura, K. L. Wang*, “Topological spintronics and magnetoelectronics”, Nature Materials 21, 15-23 (2022).

12. A. J. Grutter, Q. L. He, “Magnetic proximity effects in topological insulator heterostructures: Implementation and characterization”, Physical ReviewMaterials 5, 090301 (2021).

13. Q. Yao, Y. Ji, P. Chen, Q. L. He and X. Kou, “Topological insulators-based magnetic heterostructures”, Advances in Physics: X, 6:1, 1870560 (2021).

14. H. Sun, Q. L. He*, “Physical problems and experimental progress in layered magnetic topological materials”, Acta Physica Sincia 70, 127302 (2021).

15. L. Pan#, X. Liu#, Q. L. He#, A. Stern, G. Yin, X. Che, Q. Shao, P. Zhang, P. Deng, C.-Y. Yang, B. Casas, E. S. Choi, J. Xia, X. Kou and K. L. Wang*, “Probing the low-temperature limit of the quantum anomalous Hall effect”, Science Advances 6: eaaz3595 (2020).

16. L. Pan, A. Grutter, P. Zhang, X. Che, T. Nozaki, A. Stern, M. Street, B. Zhang, B. Casas, Q. L. He, E. S. Choi, S. M. Disseler, D. A. Gilbert, G. Yin, Q. Shao, P. Deng, Y. Wu, X. Liu, X. Kou, S. Masashi, X. Han, C. Binek, S. Chambers, J. Xia, K. L. Wang, “Observation of quantum anomalous Hall effect and exchange interaction in topological insulator/antiferromagnet heterostructure”, Advanced Materials 32, 2001460 (2020).

17. C.-Y. Yang, L. Pan, A. J. Grutter, H. Wang, X. Che, Q. L. He, Y. Wu, D. A. Gilbert, P. Shafer, E. Arenholz, H. Wu, G. Yin, P. Deng, J. A. Borchers, W. Ratcliff II and K. L. Wang, “Termination switching of antiferromagnetic proximity effect in topological insulator”, Science Advances 6: eaaz8463 (2020).

18. J. Shen, J. Lyu, J. Z. Gao, Y.-M. Xie, C.-Z. Chen, C.-w. Cho, O. Atanov, Z. Chen, K. Liu, Y. J. Hu, K. Y. Yip, S. K. Goh, Q. L. He, L. Pan, K. L. Wang, K. T. Law, and R. Lortz, “Spectroscopic fingerprint of chiral Majorana modes at the edge of a quantum anomalous Hall insulator/superconductor heterostructure”, Proceedings of the National Academy of Sciences of the United States of America 117(1) 238-242 (2019).

19. M. He, H. Sun, and Q. L. He*, “Topological insulator: Spintronics and quantum computations”, Frontiers of Physics 14, 43401 (2019).

20. Q. Shao, Y. Liu, G. Yu, S. K. Kim, X. Che, C. Tang, Q. L. He, Y. Tserkovnyak, J. Shi & K. L. Wang, “Topological Hall effect at above room temperature in heterostructures composed of a magnetic insulator and a heavy metal”, Nature Electronics 2, 182–186 (2019).

21. Q. Shao, A. Grutter, Y. Liu, G. Yu, C.-Y. Yang, D. A. Gilbert, E. Arenholz, P. Shafer, X. Che, C. Tang, M. Aldosary, A. Navabi, Q. L. He, B. J. Kirby, J. Shi, and K. L. Wang, “Exploring interfacial exchange coupling and sublattice effect in heavy metal/ferrimagnetic insulator heterostructures using Hall measurements, x-ray magnetic circular dichroism, and neutron reflectometry”, Physical Review B 99, 104401 (2019).

22. Y. Fan, Q. Shao, L. Pan, X. Che, Q. L. He, G. Yin, C. Zheng, G. Yu, T. Nie, M. R. Masir, A. H. MacDonald, K. L. Wang, “Unidirectional magneto-resistance in modulation-doped magnetic topological insulators”, Nano Letters 19, 2, 692-698 (2019).

23. Q. L. He*, “Topological superconductivity and Majorana fermion”, Chinese Science Bulletin 2018, 63: 2717–2730.

24. Q. L. He#*, G. Yin#, L. Yu#, A. J. Grutter, L. Pan, C-Z Chen, X. Che, G. Yu, B. Zhang, Q. Shao, A. L. Stern, B. Casas, J. Xia, X. Han, B. J. Kirby, R. K. Lake, K. T. Law, and K. L. Wang*, “Topological transitions induced by antiferromagnetism in a thin-film topological insulator”, Physical Review Letters 121, 096802 (2018).

25. Q. L. He#*, G. Yin#, A. J. Grutter#, L. Pan, X. Che, G. Yu, D. A. Gilbert, S. M. Disseler, Y. Liu, P. Shafer, B. Zhang, Y. Wu, B. J. Kirby, E. Arenholz, R. K. Lake, X. Han, K. L. Wang*, “Exchange-biasing topological charges by antiferromagnetism”, Nature Communications 9, 2767 (2018).

26. C. He, G. Yu, C. Grezes, J. Feng, Z. Zhao, S. A. Razavi, Q. Shao, A. Navabi, X. Li, Q. L. He, M. Li, J. Zhang, K. L. Wong, D. Wei, G. Zhang, X. Han, P. K. Amiri, and K. L. Wang, “Spin-torque ferromagnetic resonance in W/Co−Fe−B/W/Co−Fe−B/MgO stacks”, Physical Review Applied 10, 034067 (2018).

27. Q. Shao, C. Tang, G. Yu, A. Navabi, H. Wu, C. He, J. Li, P. Upadhyaya, P. Zhang, S. A. Razavi, Q. L. He, Y. Liu, P. Yang, S. K. Kim, C. Zheng, Y. Liu, L. Pan, R. K. Lake, X. Han, Y. Tserkovnyak, J. Shi & K. L. Wang, “Role of dimensional crossover on spin-orbit torque efficiency in magnetic insulator thin films”, Nature Communications 9, 3612 (2018).

28. X. Che, K. Murata, L. Pan, Q. L. He, G. Yu, Q. Shao, G. Yin, P. Deng, Y. Fan, B. Ma, X. Liang, B. Zhang, X. Han, L. Bi, Q.-H. Yang, H. Zhang, K. L. Wang, “Proximity-induced magnetic order in a transferred topological insulator thin film on a magnetic insulator”, ACS Nano 2018, 12, 5042−5050.

29. G. Yu, A. Jenkins, X. Ma, S. A. Razavi, C. He, G. Yin, Q. Shao, Q. L. He, H. Wu, W. Li, W. Jiang, X. Han , X. Li, A. C. B. Jayich, P. K. Amiri, and K. L. Wang, “Room-temperature skyrmions in an antiferromagnet-based heterostructure”, Nano Letters 2018, 18 (2), pp 980–986.

30. Q. L. He#*, X. Kou#, A. J. Grutter#, G. Yin#, L. Pan, X. Che, Y. Liu, T. Nie, B. Zhang, S. M. Disseler, B. J. Kirby, W. Ratcliff II, Q. Shao, K. Murata, X. Zhu, G. Yu, Y. Fan, M. Montazeri, X. Han, J. A. Borchers, and K. L. Wang*, “Tailoring exchange couplings in magnetic topological insulator/antiferromagnet heterostructures”, Nature Materials 16, 94–100 (2017).

31. M. K. Cheng, J. Liang, Y. H. Lai, L. X. Pang, Y. Liu, J. Y. Shen, J. Q. Hou, Q. L. He, B. C. Xu, J. S. Chen, G. Wang, C. Liu, R. Lortz, and I. K. Sou, “Large-area epitaxial growth of MoSe2 via incandescent molybdenum source”, Nanotechnology 28 (2017), p. 455601.

32. C. He, A. Navabi, Q. Shao, G. Yu, D. Wu, W. Zhu, C. Zheng, X. Li, Q. L. He, S. A. Razavi, K. L. Wong, Z. Zhang; P. K. Amiri, K. L. Wang, “Spin-torque ferromagnetic resonance measurements utilizing spin Hall magnetoresistance in W/Co40Fe40B20/MgO structures”, Applied Physics Letters 109, 202404 (2016).

33. T. Nie, J. Tang, X. Kou, Y. Gen, S. Lee, X. Zhu, Q. L. He, L.-T. Chang, K. Murata, Y. Fan, and K. L. Wang, “Enhancing electric-field control of ferromagnetism through nanoscale engineering of high-Tc MnxGe1−x nanomesh”, Nature Communications 7, 12866 (2016).

34. M. Q. He, J. Y. Shen, A. P. Petrović, Q. L. He, H. C. Liu, Y. Zheng, C. H. Wong, Q. H. Chen, J. N. Wang, K. T. Law, I. K. Sou, and R. Lortz, “Pseudogap and proximity effect in the Bi2Te3/Fe1+yTe interfacial superconductor”, Scientific Reports 6, 32508 (2016).

35. C. L. Dean, M. N. Kunchur, Q. L. He, H. Liu, J. Wang, R. Lortz, and I. K. Sou, “Current driven vortex-antivortex pair breaking and vortex explosion in the Bi2Te3/FeTe interfacial superconductor”, Physica C: Superconductivity and its applications 527 (2016) 46–49.

36. H.-C. Liu, H. Li, Q. L. He, I. K. Sou, S. K. Goh, and J. Wang, “Robust two-dimensional superconductivity and vortex system in Bi2Te3/FeTe heterostructures”, Scientific Reports 6, 26168 (2016).

37. Q. L. He#, Y. H. Lai#, Y. Liu, E. Beltjens, J. Qi, and I. K. Sou*, “High performance CaS solar-blind ultraviolet photodiodes fabricated by seed-layer-assisted growth”, Applied Physics Letters 107, 181903 (2015).

38. Q. L. He, M. He, J. Shen, Y. H. Lai, Y. Liu, H. Liu, H. He, G. Wang, J. Wang, R. Lortz, and I. K. Sou, “Anisotropic magnetic responses of a 2D-superconducting Bi2Te3/FeTe heterostructure”, Journal of Physics: Condensed Matter 27, 345701 (2015).

39. M. N. Kunchur, C. L. Dean, N. S. Moghadam, J. M. Knight, Q. L. He, H. Liu, J. Wang, R. Lortz, I. K. Sou, and A. Gurevich, “Current-induced depairing in the Bi2Te3/FeTe interfacial superconductor”, Physical Review B 92, 094502 (2015).

40. Q. L. He#, H. Liu#, M. He, Y. H. Lai, H. He, G. Wang, K. T. Law, R. Lortz, J. Wang, and I. K. Sou*, “Two-dimensional superconductivity at the interface of a Bi2Te3/FeTe heterostructure”, Nature Communications 5:4247 (2014).

41. H.-C. Liu, H.-Z. Lu, H.-T. He, B. Li, S.-G. Liu, Q. L. He, G. Wang, I. K. Sou, S.-Q. Shen, and J. Wang, “Tunable interaction-induced localization of surface electrons in antidot nanostructured Bi2Te3 thin films”, ACS Nano 8(9), 9616-9621 (2014).

42. G. Wang, Q. L. He, H.-T. He, H. Liu, M. He, J. Wang, R. Lortz, G. Wong, I. K. Sou, “Formation mechanism of superconducting Fe1+xTe/Bi2Te3 bilayer synthesized via interfacial chemical reactions”, Crystal Growth & Design 2014, 14 (7), pp 3370–3374.

43. H.-C. Liu, H.-T. He, B.-K. Li, S.-G. Liu, Q. L. He, G. Wang, I.-K. Sou, and J. Wang, “Interface effect in Nb-Bi2Te3 hybrid structure”, Applied Physics Letters 103, 152601 (2013).

44. Q. L. He, Y. H. Lai, Y. Lu, K. T. Law, and I. K. Sou, “Surface reactivity enhancement on a Pd/Bi2Te3 heterostructure through robust topological surface states”, Scientific Reports 3 : 2497 (2013).

45. Y. H. Lai, Q. L. He, W. Y. Cheung, S. K. Lok, K. S. Wong, S. K. Ho, K. W. Tam, and I. K. Sou, “Molecular beam epitaxy-grown wurtzite MgS thin films for solar-blind ultra-violet detection”, Applied Physics Letters 102, 171104 (2013).

（3）专利情况

(1) Qinglin He; Ying Hoi Lai; Yi Liu; Iam Keong Sou ; Semiconductor device and method of

forming the same, 美国, US10872996B2, 2020-12-22

(2) 何庆林; 赖英凯; 刘艺; 苏荫强; 半导体器件及其制作方法, 发明专利，专利号：201680040005.4，已授权，授权时间：2021.11.26

教学工作

主讲课程

专业英语

获奖与荣誉

荣誉称号

2017年MIT TR35 China Innovators Under 35先锋者；

2018年Forbes China 30 Under 30；

2018年入选国家海外引才计划青年项目；

2026年当选国际科学组织Vebleo协会会士。