个人简介
工作经历
2014.8- 北京大学工学院力学与工程科学系 研究员(正高)
2007.10-2014.7 北京大学工学院力学与空天技术系 特聘研究员
2005.3-2007.7 加拿大不列颠哥伦比亚大学机械工程系 博士后
教育经历
2000.9-2004.7 清华大学 固体力学 博士
1997.9-2000.7 大连理工大学 港口、海岸及近海工程 硕士
1993.9-1997.7 哈尔滨工程大学 船舶与海洋工程 学士
研究领域
1、 压电材料及传感器器件
2、 结构健康监测,金属疲劳损伤检测
3、 金属与陶瓷高温模量及内耗测量
4、 高温合金热处理工艺
近期论文
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1. M.Y. Xie, F.X. Li*. New method enables multifunctional measurement of elastic moduli and internal frictions. Journal of Applied Physics, 128, 230902, 2020 (Invited Perspective and Featured Article)
2. M.Y. Xie, F.X. Li*. A modified piezoelectric ultrasonic composite oscillator technique for simultaneous measurement of elastic moduli and internal frictions at varied temperature. Review of Scientific Instruments, 91: 015110, 2020 (Selected as Editor’s Pick)
3. Q. Huan, M.T. Chen, F.X. Li*. A high-sensitivity and long-distance structural health monitoring system based on bidirectional SH wave phased array. Ultrasonics, 108:106190,2020
4. Q. Huan, M.T. Chen, F.X. Li*. Long-distance structural health monitoring of buried pipes using pitch-catch T(0,1) wave piezoelectric ring array transducers. Ultrasonics, 106:106162,2020.
5. M.T. Chen, Q. Huan, F.X. Li*. Excitation of moderate-frequency Love wave in a Plexiglas plate on aluminum semi-space. Journal of the Acoustic Society of America, 146(6), EL482, 2019
6. H. Qiu, M.T. Chen, Q. Huan, F.X. Li*. Steering and focusing of fundamental shear horizontal guided wave in plates by using multiple-strip metasurfaces. EPL, 127: 46006 (2019)
7. M.T. Chen, Q. Huan, Z.Q. Su, F.X. Li*. A tunable bidirectional SH wave transducer based on antiparallel thickness-shear (d15) piezoelectric strips. Ultrasonics 98: 35-50, 2019.
8. Q. Huan, M.T. Chen, F.X. Li*. A practical omni-directional SH wave transducer for structural health monitoring based on two thickness-poled piezoelectric half-rings. Ultrasonics 94: 342-349, 2019.
9. Q.Z. Wang, F.X. Li*. A low-working-field (2kV/mm), large-strain (>0.5%) piezoelectric multilayer actuator based on periodically orthogonal poled PZT ceramics. Sensors and Actuators A-Physical 2018, 272:212-216
10. G. Wang, C. Tan, F.X. Li*. A contact resonance viscometer based on the electromechanical impedance of a piezoelectric cantilever. Sensors and Actuators A-Physical, 2017, 267: 401–408
11. 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. J. Appl Phys 2017, 122: 074103 (Featured Article, and highlighted by AIP Scilight: http://aip.scitation.org/doi/full/10.1063/1.5000153)
12. 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 Mater Struct. 26: 025021, 2017
13. H.C. Miao, Q. Huan, F.X. Li*. Excitation and reception of pure shear horizontal waves by using face-shear piezoelectric wafers. Smart Mater Struct. 25: 11LT01, 2016 (Selected as 2016 Highlight)
14. H.C. Miao, F.X. Li*. Realization of face-shear piezoelectric coefficient d36 in PZT ceramics via ferroelastic domain engineering. Appl Phys Lett 107, 122902, 2015
15. Ji Fu, Chi Tan, Faxin Li*. Quantitative electromechanical impedance method for nondestructive testing based on a piezoelectric bimorph cantilever. Smart Mater Struct. 065038, 2015
16. J. Fu, F.X. Li*. A forefinger-like tactile sensor for elasticity sensing based on piezoelectric cantilevers. Sensors & Actuators A Physical 234: 351–358,2015
17. J. Fu, X.L. Zhou, F.X. Li*. An adaptive nanoindentation system based on electric bending of a piezoelectric cantilever. Sensors & Actuators A 216: 249-256, 2014
18. Hongchen Miao, Xilong Zhou, Shuxiang Dong, Haosu Luo, Faxin Li*. Magnetic-field-induced ferroelectric polarization reversal in magnetoelectric composites revealed by piezorespone force microscopy. Nanoscale 6, 8515, 2014.
19. Ji Fu, Faxin Li*. An elastography method based on the scanning contact resonance of a piezoelectric cantilever. Med Phys, 40: 123502, 2013
20. Yingwei Li, James Scott, Daining Fang, Faxin Li*. 90-degree polarization switching in BaTiO3 crystals without domain wall motion. Appl Phys Lett, 103, 232901, 2013 (Cover Featured Article)
21. Y.W. Li, X.B. Ren, F.X. Li*, H.S. Luo, D.N. Fang*. Large and electric field tunable superelasticity in BaTiO3 crystals predicted by an incremental domain switching criterion. Appl Phys Lett, 102, 092905, 2013 (Cited by Science Perspective on 2013.9.27)
22. X.L. Zhou, J. Fu, F.X. Li*. Contact resonance force microscopy for nanomechanical characterization: accuracy and sensitivity. J Appl Phys 114, 064301, 2013
23. J. Fu, L.Z. Lin, X.L. Zhou, Y.W. Li, F.X. Li*. A macroscopic non-destructive testing system based on the cantilever-sample contact resonance. Review of Scientific Instruments. 83: 123707, 2012
24. Y.W. Li, X.L. Zhou, F.X. Li*. Temperature dependent mechanical depolarization of ferroelectric ceramics. J Phys D-Appl Phys 43, 175501, 2010
25. F.X. Li, R.K.N.D. Rajapakse, A constrained domain switching model for polycrystalline ferroelectric ceramics. Part I: model formulation and application to tetragonal materials. Acta Mater, 55: 6472-6480, 2007
26. Faxin Li and Daining Fang, Effects of electrical boundary conditions and poling approaches on the mechanical depolarization behavior of PZT ceramics. Acta Mater., 53: 2665-2673, 2005
27. Faxin Li and Daining Fang, Simulations of domain switching in ferroelectrics by a three-dimensional finite element model, Mech Mater, 36(10): 959-973, 2004
28. 王刚,李法新*。基于水平剪切超声导波的高温管道壁厚在线监测。无损检测,41(9):1-6, 2019
29. 周锡龙*,李法新*,付际。扫描探针声学显微技术研究进展, 固体力学学报,37(2): 107-134, 2016
30. 高鹏,李法新*。非线性超声相控阵无损检测系统及实验研究,实验力学, 2014, 29(1): 1-11
学术兼职
学术兼职
Reviewer for J Appl Phys, J Phys: Condens Matter, J Phys D: Appl Phys, Smart Mater Struct., J. Mater. Sci., Mater Lett., J Alloy Comp., etc
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