朱礼军, 研究员,博导,课题组长, 半导体芯片物理与技术全国重点实验室副主任
2009年本科毕业于北京师范大学物理学系,2014年博士毕业于中国科学院半导体所半导体超晶格国家重点实验室,2014-2021年先后在德国马丁路德大学和美国康奈尔大学工作。2021年入选国家海外高层次人才计划和中科院BR计划, 并全职回国加入了半导体芯片物理与技术全国重点实验室担任研究员、课题组长和实验室副主任。
主要从事国际最前沿的第三代自旋电子器件关键操控原理和应用的实验研究,发展后摩尔高算力存储/传感/计算新原理器件,在PRL、Nature/Science子刊、Advanced Materials等发表高水平论文80余篇,申请专利10项,在APS、MRS、SPIE、MMM、ICM等国际顶级会议做特邀报告30余次。现任中国物理学会低温物理专业委员会委员、《npj Spintronics》副主编、《Communications Materials》编委、《半导体学报》编委和PRL、Nature/Science子刊、Advanced Materials等期刊审稿专家,多次为Advanced Materials、Applied Physics Reviews等领域内顶级期刊撰写综述文章评述领域内关键科学问题和发展趋势,现主持承担科技部、基金委、北京市等科研任务多项。
主要研究方向:薄膜和层状磁性材料、自旋轨道矩物理和材料、自旋存感算器件
招生招聘:
课题组研究设备一流、学术氛围浓厚、充满创新活力和具有国际影响力,成员分别来自中科大、北师大、武汉大学、吉林大学、哈工大、北京科技大学、美国特拉华大学等,所培养博士后获基金委青年基金、重点研发子课题等项目支持,所培养研究生多次获国家奖学金、专业特等奖学金、中国物理学会秋季会议最佳墙报奖等,毕业生主要就业于一流科研院所、高校和高科技企业,优秀毕业生可获得留所工作或推荐到国外顶级研究组继续深造。
招生专业为凝聚态物理(A+)和材料(A),欢迎责任心强、科研兴趣浓厚、能自我管理、基础扎实的物理/材料/微电子背景的优秀本科生申请硕博研究生。
课题组常年招聘自旋电子学和二维材料方向的博士后、科研助理、助研/副研/研究员等不同层次青年优秀人才,优秀博士后出站可优先入编留所工作。
课题组网站:https://www.x-mol.com/groups/ZhuGroup-semiCAS
联系方式:Email: ljzhu@semi.ac.cn 电话:010-82304981
近5年代表性通讯作者论文:
1. Q. Liu, L. Zhu*, Absence of Orbital Current Torque in Ta/ferromagnet Bilayers, Nature Communications (2025), revised.
2. L. Zhu* et al., Physics Origin of Universal Unusual Magnetoresistance, National Science Review 12, nwaf240 (2025).
3. Z. Li, … L. Zhu*, Microscopic Mechanisms of Strong Electron Scattering and Giant Anomalous Hall Effect in high-Curie-temperature Fe3GaTe2 van der Waals Films, Advanced Functional Materials 35, 2512048 (2025).
4. Q. Liu, …L. Zhu*, Asymmetric magnetization switching and programmable complete Boolean logic enabled by long-range intralayer Dzyaloshinskii-Moriya interaction, Nature Communications 15, 2978 (2024)
5. Q. Liu, … L. Zhu*, Efficient generation of out-of-plane polarized spin current in polycrystalline heavy metal devices with broken electric symmetries, Advanced Materials, 36, 2406552 (2024)
6. L. Zhu*, D.C. Ralph, Strong variation of spin-orbit torques with relative spin relaxation rates in ferrimagnets, Nature Communications 14, 1778 (2023).
7. L. Zhu*, Switching of Perpendicular Magnetization by Spin-Orbit Torque, Advanced Materials, 35, 2300853 (2023).
8. Q. Liu, X. Lin, L. Zhu*, Absence of Spin-Orbit Torque and Discovery of Anisotropic Planar Nernst Effect in CoFe Single Crystal, Advanced Science, 10, 2301409 (2023).
9. X. Lin, … L. Zhu*, Giant, Linearly Increasing Spin−Orbit Torque Efficiency in Symmetry-Broken Spin−Orbit Torque Superlattices, Nano Letters 23, 9420 (2023).
10. Q. Liu, L. Zhu* et al., Giant bulk spin–orbit torque and efficient electrical switching in single ferrimagnetic FeTb layers with strong perpendicular magnetic anisotropy, Applied Physics Reviews 9, 021402 (2022).
11. Q. Liu, L. Zhu*, Current-induced perpendicular effective magnetic field in magnetic heterostructures, Applied Physics Reviews 9, 041401 (2022).
12. L. Zhu* et al., Fully spin-transparent magnetic interfaces enabled by insertion of a thin paramagnetic NiO layer, Physical Review Letters 126, 107204 (2021).
13. L. Zhu* et al., Maximizing Spin-Orbit Torque Generated by the Spin Hall Effect of Pt, Applied Physics Reviews 8, 031308 (2021).
14. L. Zhu* et al., Unveiling the mechanism of bulk spin-orbit torques within chemically disordered FexPt1-x single layers, Advanced Functional Materials 31, 2103898 (2021).
15. L. Zhu* et al., Observation of strong bulk damping-like spin-orbit torque in chemically disordered ferromagnetic single layers, Advanced Functional Materials 30, 2005201 (2020).
16. L. Zhu* et al., Strong and tunable anti-damping spin-orbit torque and Dzyaloshinskii-Moriya interaction generated by low-resistivity Pd1-xPtx alloys, Advanced Functional Materials 29, 1805822 (2019).
17. L. Zhu* et al., Variation of the giant spin Hall conductivity of Pt with carrier lifetime, Science Advances 5, eaav8025 (2019).
18. L. Zhu* et al., Effective spin mixing conductance of the heavy-metal-ferromagnet interfaces, Physical Review Letters 123, 057203 (2019).
19. L. Zhu* et al., Spin-orbit torques in heavy-metal-ferromagnet bilayers with varying strengths of interfacial spin-orbit coupling, Physical Review Letters 122, 077201 (2019).