2012年在西南交通大学获得工程力学专业学士学位，2017年在北京大学获得固体力学专业博士学位

[1]国家自然科学基金青年项目（11802249），“周向SH导波的激励机理、压电换能器设计及其用于管道健康监测的研究”，2019.01-2021.12 [2]西南交通大学引进人才启动项目

在Applied Physics Letters，Smart materials and Structures，Physical Review Applied等领域主流期刊上发表SCI论文20余篇，被包括Science在内的国际一流期刊引用350余次（谷歌学术数据）。[22] H. Zhang, Y.H. Du, J.H. Tang, G.Z. Kang, H.C. Miao*. Circumferential SH Wave Piezoelectric Transducer System for Monitoring Corrosion-Like Defect in Large-Diameter Pipes. Sensors, 2020, 20, 460 (20pp). [21]M.Y. Zheng, X.N. Liu, Y. Chen, H.C. Miao, R. Zhu*, and G.K. Hu*. Theory and realization of nonresonant anisotropic singly polarized solids carrying only shear waves, Physical Review Applied, 2019, 12, 014027. [20]H.C. Miao*, X. Lei, Hao, Zhang. SH guided wave excitation by an apparent face-shear mode (d36) piezocomposite transducer: experiments and theory. Smart materials and Structures, 2019, 28,115045 (16pp). [19]H.C. Miao*, Q. Huan, F.X. Li*,G.Z.Kang.A variable-frequency bidirectional shear horizontal (SH) wave transducer based on dual face-shear (d24) piezoelectric wafers.Ultrasonics, 2018,89,13-21. [18]Q. Huan, H.C. Miao, F.X. Li*.A variable-frequency structural health monitoring system based on omnidirectional shear horizontal wave piezoelectric transducers.Smart materials and Structures, 2018，27,025008 [17]Q. Huan, H.C. Miao, F.X. Li*.Generation and reception of shear horizontal waves using the synthetic face-shear mode of a thickness-poled piezoelectric wafer.Ultrasonics, 2018,86,20-27. [16]H.C. Miao, Q. Huan, Q.Z. Wang, F.X. Li*. A New Omnidirectional Shear Horizontal Wave Transducer Using Face-shear (d24) Piezoelectric Ring Array. Ultrasonics, 2017, 74,167-173. [15]H.C. Miao, Q. Huan, Q.Z. Wang, F.X. Li*. Excitation and reception of single torsional wave T(0,1) mode in pipes using face-shear d24 piezoelectric ring array. Smart materials and Structures, 2017,26,025021. [14]H.C. Miao, F.X. Li*. An energy-consistent fracture model for ferroelectrics. Acta Mechanica Sinica,2017, 33,106-119. [13]Q. Huan, H.C. Miao, F.X. Li*. A uniform-sensitivity omnidirectional shearhorizontal (SH) wave transducer based on a thickness poled, thickness-shear (d15) piezoelectric ring. Smart materials and Structures, 2017，26， 08LT01 [12]F.X. Li*，Q.Z. Wang,H.C. Miao.Giant actuation strain nearly 0.6% in a periodically orthogonal poled lead titanate zirconate ceramic via reversible domain switching. Journal of applied Physics,2017,122,074103.(入选当期封面，并作为亮点报道) [11]H.C. Miao, S.X. Dong, F.X. Li*. Excitation of fundamental shear horizontal wave by using face-shear (d36) piezoelectric ceramics. Journal of applied Physics, 2016, 119, 174101. [10]F.X. Li*, H.C. Miao(导师一作). Development of an apparent face-shear mode (d36) piezoelectric transducer for excitation and reception of shear horizontal waves via two-dimensional antiparallel poling. Journal of applied Physics ,2016, 120, 144101. [9]H.C. Miao, Q. Huan, F.X. Li*. Excitation and reception of pure shear horizontal waves by using face-shear d24 mode piezoelectric wafers. Smart materials and Structures, 2016, 25, 11LT01. （入选2016年度亮点论文） [8]H.C. Miao, F.X. Li*. Realization of face-shear piezoelectric coefficient d36 in PZT ceramics via ferroelastic domain engineering. Applied Physics Letters, 2015,107, 122902. [7]H.C. Miao, X. Chen, H.R. Cai, F.X. Li*. Comparative face-shear piezoelectric properties of soft and hard PZT ceramics. Journal of applied Physics, 2015, 118, 214102. [6]H.C. Miao, X.L. Zhou, S.X. Dong, H.S. Luo, F.X. Li*. Magnetic-field-induced ferroelectric polarization reversal in magnetoelectric composites revealed by piezoresponse force microscopy. Nanoscale, 2014, 6, 8515. [5]H.C. Miao, C. Tan, X.L. Zhou, X. Y. Wei, F.X. Li*. More ferroelectrics discovered by switching spectroscopy piezoresponse force microscopy? EPL, 2014, 108, 27010. [4]H.C. Miao, Y. Sun, X.L. Zhou, Y.W. Li, F.X. Li*. Piezoelectricity and ferroelectricity of cellular polypropylene electrets films characterized by piezoresponse force microscopy. Journal of applied Physics, 2014, 116, 066820. [3]X.L. Zhou, J. Fu, H.C. Miao, F.X. Li*. Contact resonance force microscopy with higher-eigenmode for nanoscale viscoelasticity measurements, Journal of applied Physics, 2014, 116, 034310. [2]X.L. Zhou, H.C. Miao, F.X. Li*. Nanoscale structural and functional mapping of nacre by scanning probe microscopy techniques. Nanoscale, 2013, 5, 11885. [1]Y.W. Li, X.L. Zhou, H.C. Miao, H.R. Cai, F.X. Li*. Mechanism of crystal-symmetry dependent deformation in ferroelectric ceramics: Experiments versus model, Journal of applied Physics, 2013,113, 214111.

授权国家发明专利6项，实用新型专利2项，申请软件著作权1项。主要专利： [1] 李法新，苗鸿臣，谭池。用于激励和和接收非弥散超声导波的压电换能器及制备方法。中国发明专利，专利号：ZL 201610213142.5，授权公告日：2018年08月10日。 [2] 李法新，苗鸿臣。一种基于铁弹畴变的大致动应变压电致动器。中国发明专利，专利号：ZL 201510031542.X，授权公告日：2017年02月22日。 [3] 李法新，苗鸿臣。具有压电系数d36的压电陶瓷及其制备方法。中国发明专利，专利号: Zࣺᯬ