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刘正猷
中国科学院院士,武汉大学物理科学与技术学院院长、教授
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详细介绍
刘正猷
中国科学院院士,武汉大学物理科学与技术学院院长、教授
个人履历:
刘正猷:男,汉族,1965年9月出生,湖北鄂州人,中国科学院院士,武汉大学物理科学与技术学院院长,教授,博士生导师,教育部重大人才计划特聘教授,国家杰出青年基金获得者,入选国家高层次人才特殊支持计划。兼任:Physical Review Letters编委及Divisional Associate Editor(DAE)、《中国物理快报》、《国家科学评论》和《科学通报》等期刊编委。1986年、1989年和1993年在武汉大学物理学系分别获学士、硕士及博士学位。1993年7月-2001年4月在华南理工大学应用物理学系历任讲师、副教授、教授,2001年4月至今,在武汉大学物理科学与技术学院任教授。刘正猷教授主要研究兴趣包括声学超材料、拓扑声学、声子晶体、声场调控及声场与颗粒相互作用等。主持国家自然科学基金项目、国家重点研发计划、广东省自然科学基金项目、湖北省自然科学基金等科研课题多项;在《Science》《Nature》《Nature Physics》《Nature Materials》《Nature Communications》《Physical Review Letters》《Science Advances》等期刊上发表论文200余篇,论文SCI他引总计超过13000次,单篇论文SCI他引最高超过3000次,历年均入选Elsevier发布的中国高被引学者榜。以第一完成人获国家自然科学二等奖、湖北省自然科学一等奖、国际声子学学会布里渊奖等奖项。
论文代表:
Acoustic exceptional line semimetal, Physical Review Letters, 134(11)(2025) 116606.
Hinge modes of surface arcs in a synthetic Weyl phononic crystal, Physical Review Letters, 133(12)(2024), 126602.
Topological network modes in a twisted moiré phononic crystal, Physical Review Letters, 132(26)(2024), 266602.
Observation of higher-order nodal-line semimetal in phononic crystals, Physical Review Letters, 132(6)(2024), 066601.
Observation of geometry-dependent skin effect in non-Hermitian phononic crystals with exceptional points, Nature Communications, 14(1)(2023), 4569.
antichirality emergent in type-II Weyl phononic crystals, Physical Review Letters, 130(26)(2023), 266304.
Acoustic higher-order Weyl semimetal with bound hinge states in the continuum, Physical Review Letters, 130(11)(2023), 116103.
Topological materials for full-vector elastic waves, National Science Review, 10(5)(2023), nwac203.
Topological dislocation modes in three-dimensional acoustic topological insulators, Nature Communications, 13(1)(2022), 508.
Observation of boundary induced chiral anomaly bulk states and their transport properties, Nature Communications, 13(1)(2022), 5916.
Experimental observation of non-abelian earring nodal links in phononic crystals, Physical Review Letters, 128(24)(2022), 246601.
Higher-order topological semimetal in acoustic crystals, Nature Materials, 20(6)(2021), 812-817.
3D hinge transport in acoustic higher-order topological insulators, Physical Review Letters, 127(25)(2021), 255501.
Hybrid-order topological insulators in a phononic crystal, Physical Review Letters, 126(15)(2021), 156801.
Pseudomagnetic fields enabled manipulation of on-chip elastic waves, Physical Review Letters, 127(13)(2021), 136401.
Acoustic higher-order topology derived from first-order with built-in Zeeman-like fields, Science Bulletin, 67(5)(2021), 488-494.
Experimental characterization of fragile topology in an acoustic metamaterial, Science, 367(6479)(2020), 797-800.
Valley-locked waveguide transport in acoustic heterostructures, Nature Communications, 11(1)(2020), 3000.
Acoustic spin-Chern insulator induced by synthetic spin-orbit coupling with spin conservation breaking, Nature Communications, 11(1)(2020), 3227.
Observation of quadratic Weyl points and double-helicoid arcs, Nature Communications, 11(1)(2020), 1820.
Ideal type-II Weyl phase and topological transition in phononic crystals, Physical Review Letters, 124(20)(2020), 206802.
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