JOURNAL PUBLICATIONS (*Corresponding author)

(发表SCI论文100余篇，总引用1300余次)

Journals (标*为通讯作者)

 

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.      Q.Z. Wang, F.X. Li*. Controllable thermal expansion in ferroelectric ceramics through two-dimensional periodically orthogonal poling. Scripta Materiala, 191：67–70, 2021

3.      M.Y. Xie, F.X. Li*. Measurement of elastic moduli and internal frictions using modified piezoelectric ultrasonic composite oscillator technique with large frequency mismatch. Review of Scientific Instruments. 91, 076106，2020

4.      M.T. Chen, Q. Huan, F.X. Li*. A unidirectional SH wave transducer based on phase-controlled antiparallel thickness-shear (d15) piezoelectric strips. Theoretical and Applied Mechanics Letters, 10: 299-306, 2020

5.      Q.Z. Wang, F.X. Li*. Morphotropic phase boundary-like effect in hybrid electrically poled, mechanically depolarized ferroelectric ceramics. Journal of Applied Physics 128, 054104, 2020

6.      H. Qiu, F.X. Li*. Manipulation of shear horizontal guided wave with arbitrary wave fronts by using metasurfaces. Journal of Physics D-Applied Physics, 53: 285301, 2020

7.      M.Y. Xie, F.X. Li*. Anomalous elastic moduli and internal frictions in unpoled and poled lead titanate zirconate ceramics near the Curie temperature. AIP Advances, 10(4): 045007, 2020

8.      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

9.      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.

10.   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)

11.  M.Y. Xie, Q. Huan, F.X. Li*. Quick and repeatable shear modulus measurement based on torsional resonance using a piezoelectric torsional transducer. Ultrasonics 103: 106101, 2020

12.  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

13.  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)

14.  Q. Huan, F.X. Li*. A baseline-free SH wave sparse array system for structural health monitoring.  Smart Mater Struct. 28: 105010, 2019

15.  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.

16.  Q. Huan, M.T. Chen, Z.Q. Su, F.X. Li*. A high-resolution structural health monitoring system based on SH wave piezoelectric transducer phased array. Ultrasonics 97: 29-37, 2019.

17.  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.

18.  Q. Huan, M.T. Chen, A.K. Soh, F.X. Li*. Development of an omni-directional shear horizontal wave transducer based on a radially poled piezoelectric ring. Acta Mechanica Solida Sinica 32(1): 29-39, 2019.

19.  G. Wang, Q.Z. Wang, F.X. Li*. A U-shape shear horizontal waveguide sensor for on-line monitoring of liquid viscosity. Sensors and Actuators A: Physical 284: 35-41, 2018.

20.  G. Wang, F.X. Li*. An online viscosity measurement method based on the electromechanical impedance of a piezoelectric torsional transducer. IEEE Sensors Journal, 18(21): 8781-8788, 2018

21.  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

22.  Q.Z. Wang, F.X. Li^*. Large actuation strain over 0.3% in periodically orthogonal poled BaTiO3 ceramics and multilayer actuators via reversible domain switching. J Phys D: Appl Phys 2018, 51: 255301

23.  Q.Z. Wang, G. Wang, F.X. Li*. Precise, long-time displacement self-sensing of piezoelectric cantilever actuators based on charge measurement using the Sawyer–Tower circuit. Chinese Physics Letters 2018, 35(10): 107701.

24.  Q. Huan, H.C. Miao, F.X. Li^*. A variable-frequency structural health monitoring system based on omnidirectional shear horizontal wave piezoelectric transducers. Smart Mater. Struct. 2018, 27: 025008

25.  Q. Huan, M.T. Chen, F.X. Li*. A comparative study of three types shear mode piezoelectric wafers in shear horizontal wave generation and reception. Sensors 2018, 18(8): 2681.

26.  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

27.  H.C. Miao^*, Q. Huan, G.Z. Kang, F.X. Li*. A variable-frequency bidirectional shear horizontal (SH) wave transducer based on dual face-shear (d24) piezoelectric wafers. Ultrasonics 2018, 89: 13-21.

28.  H. Xu, Y.M. Pei^*, F.X. Li, D.N. Fang*. A multi-scale and multi-field coupling nonlinear constitutive theory for the layered magnetoelectric composites. Journal of the Mechanics and Physics of Solids 2018, 114: 143-157.

29.  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

30.  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)

31.  Q. Huan, H.C. Miao, F.X. Li^*. A uniform-sensitivity omnidirectional shear-horizontal (SH) wave transducer based on a thickness poled, thickness-shear (d15) piezoelectric ring. Smart Mater Struct. 2017, 26: 08LT01

32.  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

33.  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 74: 167-173, 2017

34.  H.C. Miao, F.X. Li^*. An energy-consistent fracture model for ferroelectrics. Acta Mechanica Sinica, 33(1): 106-119, 2017

35.  Y.W. Li^*, J. Wang^*, F.X. Li^*. Intrinsic polarization switching in BaTiO 3 crystal under uniaxial electromechanical loading. Physical Review B 94: 184108, 2016

36.  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)

37.  F.X. Li^*, H.C. Miao. Development of an apparent face-shear mode (d36) piezoelectric transducer for excitation and reception of shear horizontal waves via two-dimensional antiparallel poling. J. Appl Phys 120: 144101, 2016

38.  H.C. Miao, S.X. Dong, F.X. Li^*. Excitation of fundamental shear horizontal wave by using face-shear (d36) piezoelectric ceramics. J. Appl Phys 119: 174101, 2016

39.  Y.W. LI, F.X. Li^*. Domain switching criterion for ferroelectric single crystals under uniaxial electromechanical loading. Mech Mater 93: 246-256, 2016

40.  J. Fu, F.X. Li^*.  A comparative study of piezoelectric unimorph and multilayer actuators as stiffness sensors via contact resonance. Acta Mechanica Sinica, 32(4): 633-639, 2016

41.  H.C. Miao, X. Chen, H.R. Cai, F.X. Li^*.Comparative face-shear piezoelectric properties of soft and hard PZT ceramics. J. Appl Phys 118, 214102, 2015

42.  Y.W. LI, F.X. Li^*. The effect of multi-rank domain pattern on the polarization response of BaTiO3 crystal during electric field loading. J. Appl Phys 117, 244101, 2015

43.  Y.W. LI^*, Y.H. LI, F.X.LI. Creep behavior of soft and hard PZT ceramics during mechanical loading and unloading. J Eur Ceram Soc 35: 3827-3834, 2015

44.  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

45.  J. Fu, F.X. Li^*. A finger-like hardness tester based on the contact electromechanical impedance of a piezoelectric bimorph cantilever. Review of Scientific Instruments 86: 103902, 2015

46.  Ji Fu, Chi Tan, Faxin Li^*. Quantitative electromechanical impedance method for nondestructive testing based on a piezoelectric bimorph cantilever. Smart Mater Struct. 065038, 2015

47.  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

48.  Ji Fu, Yaqiong Liu, Xilong Zhou, Yingwei Li, Faxin Li^*. Local contact stiffness detection for nondestructive testing based on the contact resonance of a piezoelectric cantilever. Journal of Vibration and Acoustics-T ASME, 137, 051011, 2015

49.  Yingwei Li*, Shangming Feng, Wenping Wu, Faxin Li^*. Temperature Dependent Mechanical Property of PZT Film: An Investigation by Nanoindentation. Plos One 10(3): e0116478, 2015

50.  X. Wei*, S. Xiao, F.X. Li*, D.M. Tang, Q. Chen, Y. Bando, and D. Golberg*. Comparative Fracture Toughness of Multilayer Graphenes and Boronitrenes.  Nano Lett. 2015 (DOI: 10.1021/nl5042066)

51.  C.H. Miao, X.L. Zhou, X.Y. Wei, F.X. Li^*. More ferroelectrics discovered by switching spectroscopy piezoresponse force microscopy? EPL 108, 27010, 2014

52.  Yingwei Li, Faxin Li^*. The hysteretic response of lead zirconate titantate ceramics after mechanical depolarization. Mater Res Exp 1, 045701, 2014

53.  Ji Fu and Faxin Li^*. An Extended Scanning Probe Microscopy System for Macroscopic Topography Imaging. Microscopy Research and Technology 77: 749-753, 2014 (Cover paper)

54.  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

55.  Ji Fu, Xilong Zhou, Yanhong Guo, Faxin Li^*. Viscoelasticity mapping method based on the contact resonance of a piezoelectric cantilever. Polymer Testing 37: 138-147, 2014

56.  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.

57.  H.M. 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. J Appl Phys 116, 066820, 2014

58.  X.L. Zhou, J. Fu, C.H. Miao, F.X. Li^*. Contact resonance force microscopy with higher-eigenmode for nanoscale viscoelasticity measurements. J Appl Phys 116: 034310, 2014

59.  Yingwei Li, Faxin Li^*. The effect of domain patterns on 180-degree domain switching in BaTiO₃ crystals during antiparallel electric field loading. Appl Phys Lett, 104, 042908, 2014

60.  Z. Yu, W. Mao, F.X. Li, X. Feng, Y.M. Pei, D.N. Fang^*. Magnetic and electric bulge-test instrument for the determination of coupling mechanical properties of functional free-standing films and flexible electronics. Rev Sci Instrum. 85: 065117, 2014

61.  H. Zhou, Y.M. Pei, F.X. Li, H.S. Luo, D.N. Fang. Electric-field-tunable mechanical  properties of relaxor ferroelectric single crystal measured by nanoindentation. Appl Phys Lett, 104, 061904, 2014

62.  Y.Y. Sun, Q. Liang, H.J. Chi, Y.J. Zhang, Y. Shi, D.N. Fang*, F.X. Li. The Application of Gas Plasma Technologies in Surface Modification of Aramid Fiber. FIBERS AND POLYMERS 15 (1): 1-7, 2014

63.  J. Ma, Y.M. Pei, Y.Y. Sun, F.X. Li^*, D.N. Fang^*. Wrinkles of magnetoelectric composite thin films bonded on compliant buffer-layers. J Appl Phys 115, 083515, 2014

64.  X.L. Zhou, J. Fu, Y.W. Li, F.X. Li^*. Nanomechanical mapping of glass fiber reinforced polymer composites using atomic force acoustic microscopy. J Appl Polymer Sci , 131(2): 39800, 2014

65.  X.L. Zhou, F.X. Li^*. Simulations of nonlinear deformations in Ni-Ti shape memory alloys under tension/compression using an energy minimization model. Comp Mater Sci 81: 530-537, 2014

66.  F.X. Li^*, Y. Sun, R.K.N.D. Rajapakse. Effect of electric boundary conditions on crack propagation in ferroelectric ceramics. Acta Mech Sinica 30(2): 153-160, 2014

67.  Ji Fu, Faxin Li^*. An elastography method based on the scanning contact resonance of a piezoelectric cantilever. Med Phys, 40: 123502, 2013

68.  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)

69.  D.N. Fang^*, F.X. Li, B. Liu, Y.H. Zhang, J.W. Hong, X.H. Guo. Advances in Developing Electromechanically Coupled Computational Methods for Piezoelectrics/Ferroelectrics at Multiscale. Applied Mechanics Review 65, 060802, 2013

70.  X.L. Zhou, J. Fu, F.X. Li^*. Contact resonance force microscopy for nanomechanical characterization: accuracy and sensitivity. J Appl Phys 114, 064301, 2013

71.  X.L. Zhou, C.H. Miao, F.X. Li^*. Nanoscale structural and functional mapping of nacre by scanning probe microscopy techniques. Nanoscale 5: 11885-11893, 2013

72.  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. J. Appl. Phys.  113, 214111, 2013

73.  Y.W. Li, F.X. Li^*. Ultrahigh actuation strains in BaTiO3 and Pb(Mn1/3Nb2/3)O3-PbTiO3 single crystals via reversible electromechanical domain switching. Appl Phys Lett, 102, 152905, 2013

74.  Y.W. Li, Y. Sun, F.X. Li^*. Domain texture dependent fracture behavior in mechanically poled/depoled ferroelectric ceramics. Ceram Int. 39: 8605-8614, 2013

75.  C.Y. Zhang, F.X. Li, B. Wang. Estimation of the elasto-plastic properties of metallic materials from micro-hardness measurements. J Mater Sci. 48 (12): 4446-4451, 2013

76.  H. Zhou, Y.M. Pei, H. Huang, H.W. Zhao, F.X. Li, D.N. Fang^*. Multi-field nanoindentation apparatus for measuring local mechanical properties of materials in external magnetic and electric fields. Rev Sci Instrum. 84(6): 063906, 2013

77.  L.Z. Lin, Y.W. Li, A.K. Soh, F.X. Li^*. A pencil-like magnetoelectric sensor exhibiting ultrahigh coupling properties. J Appl Phys, 113, 134101, 2013

78.  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)

79.  Xilong Zhou, Faxin Li^*, Huarong Zeng. Mapping nanoscale domain patterns in ferroelectric ceramics by atomic force acoustic microscopy and piezoresponse force microscopy. J. Appl. Phys. 113, 187214, 2013

80.  H. Zhou, J.W. Hong, Y.H. Zhang, F.X. Li, Y.M. Pei, D.N. Fang^*. Flexoelectricity induced increase of critical thickness in epitaxial ferroelectric thin films. PHYSICA B-CONDENSED MATTER 407 (17), 3377-3381, 2012

81.  H. Zhou, J.W. Hong, Y.H. Zhang, F.X. Li, Y.M. Pei, D.N. Fang^*. External uniform electric field removing the flexoelectric effect in epitaxial ferroelectric thin films. EPL 99(4): 47003, 2012

82.  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

83.  L.Z. Lin, Y.P. Wan, F.X. Li^*. An analytical nonlinear model for laminate multiferroic composites reproducing the dc-magnetic-bias dependent magnetoelectric properties. IEEE Transactions on Ultrasonics, Ferroelectrics & Frequency Control. 59(7): 1568-1574, 2012

84.  Y.W. Li, F.X. Li^*. In situ observation of electric field induced crack propagation in BaTiO3 crystals along the field direction. Scripta Materialia 67: 601-604, 2012

85.  X.L. Zhou, F.X. Li^*. Simulations of domain evolution in morphotropic ferroelectric ceramics under electromechanical loading using an optimization-based model. J Appl Phys, 109, 084107, 2011

86.  F.X. Li^*, X. L. Zhou. Simulations of gradual domain-switching in polycrystalline ferroelectrics using an optimization-based, multidomain-grain model. Computers and Structures, 89: 1142-1147, 2011

87.  Y.W. Li, F.X. Li^*. Two-dimensional domain switching induced tensile fracture in a crack-free PZT ceramics under orthogonal electromechanical loading. Appl Phys Lett, 97, 102903, 2010.

88.  Y.W. Li, X.L. Zhou, F.X. Li^*. Temperature dependent mechanical depolarization of ferroelectric ceramics. J Phys D-Appl Phys 43, 175501, 2010

89.  F.X. Li^*, X.L. Zhou, A.K. Soh. An optimization-based “phase field” model for polycrystalline ferroelectrics. Appl Phys Lett 96:152905, 2010

90.  F.X. LI^*, A.K. Soh. An optimization-based computational model for domain evolution in polycrystalline ferroelastics. Acta Mater 58：2207-2215，2010

91.  Y.W. LI, F.X. LI^*. Large anisotropy of fracture toughness in mechanically poled/depoled ferroelectric ceramics. Scripta Mater 62 : 313-316, 2010

92.  F.X.LI^*, Y.W. LI. Modeling on domain switching in ferroelectric ceramics near the morphotropic phase boundary. J Appl Phys 105: 124105, 2009

93.  F.X. Li^*. An inverse-pole-figure method for analysis of domain switching in polycrystalline ferroelectrics/ferroelastics. Scripta Mater, 59: 677-680, 2008

94.  Y.M. Pei, D.N. Fang, F.X. LI. Giant forced volume magnetostriction in polycrystalline Tb0.3Dy0.7Fe1.95 alloys under magnetomechanical loading. J Mag Mag Mater 321: 2783-2787, 2009

95.  M. Senousy, F.X. Li, D. Mumford, M. Gadala, R.K.N.D. Rajapakse. Thermo-Electro-Mechanical Performance of Piezoelectric Stack Actuators for Fuel Injector Applications. J. Intell. Mater. Syst. Struct. 20: 387-399, 2009

96.  F.X. Li, R.K.N.D. Rajapakse. Nonlinear finite element modeling of polycrystalline ferroelectrics based on constrained domain switching. Comp Mater Sci, 44(2): 322-329, 2008

97.  F.X. Li, R.K.N.D. Rajapakse, D. Mumford, M. Gadala, Quasi-static thermo-electromechanical behavior of piezoelectric stack actuators. Smart Mater Struct. 17, 015049, 2008

98.  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

99.  F.X. Li, R.K.N.D. Rajapakse, A constrained domain switching model for polycrystalline ferroelectric ceramics. Part II: combined switching and application to rhombohedral materials. Acta Mater, 55: 6481-6488, 2007

100.             F.X. Li, R.K.N.D. Rajapakse, Analytical saturated domain orientation texture and electromechanical properties of ferroelectric ceramics due to electric/mechanical poling J. Appl Phys 101, 054110, 2007

101.             F.X. Li, X.X. Yi, Z.Q. Cong and D.N. Fang, PZT nano-composites reinforced by small amount of MgO. Modern Phys Lett B, 21(24): 1605-1610, 2007

102.             Yuanming Liu, Faxin Li and Daining Fang, Anisotropy of domain switching in pre-poled lead titanate zirconate ceramics under multi-axial electric loading, Appl Phys Lett. 90, 032905, 2007

103.             Y.J. Jiang, D.N. Fang and F.X. Li, In-situ observation of electric field induced domain switching near a crack tip in poled PMNT62/38 single crystals. Appl Phys Lett 90, 222907 2007

104.             Faxin Li, Daining Fang and Yuanming Liu, Domain switching anisotropy in poled PZT ceramics under orthogonal electromechanical loading. J. Appl. Phys. 100, 084101, 2006

105.             Faxin Li, Daining Fang and Ai-Kah Soh, Theoretical saturated domain orientation states in ferroelectric ceramics, Scripta Mater. , 54(7): 1241-1246, 2006

106.             Faxin Li, Daining Fang, J.J. Lee and K.H. Cheol, Effects of compressive stress on the nonlinear electromechanical behavior of ferroelectric ceramics, Science in China E, 49 (1): 29-37, 2006

107.             Faxin Li, Shang Li and Daining Fang, Domain switching in Ferroelectric single crystal/ceramics under electromechanical loading, Mater. Sci. Engng B, 120(1-3): 119-124, 2005

108.             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

109.             Faxin Li and Daining Fang, Effects of lateral stress on the electromechanical response of ferroelectric ceramics: Experiments versus Model, J. Intell. Mater. Syst. Struct., 16(7-8): 583-588, 2005

110.             Daining Fang, Faxin Li, Ai Kah Soh and Tieqi Liu, Analysis of the electromechnical behavior of ferroelectric ceramics based on a nonlinear finite element model. Acta Mechanica Sinica, 21(3): 294-304, 2005

111.             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

112.             Faxin Li, Daining Fang and Ai-Kah Soh, An analytical axisymmetric model for the poling-history dependent behavior of ferroelectric ceramics, Smart Mater. Struct. 13: 668-675, 2004

113.             Li Faxin, Fang Daining and Feng Xue, Effect of lateral pressure on the nonlinear behavior of PZT ceramics, Chinese Physics Letters, 20 (12): 2250-2251, 2003

114.             王强中，李法新^*。基于可逆畴变的压电圆环多层致动器应变响应研究。固体力学学报，41(2): 151-158

115.             宦强，陈铭桐，李法新^*。基于扭转导波T(0,1)的埋地管道长距离结构健康监测。无损检测，42(7)：1-4, 2020

116.             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

117. 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

118. 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

119. 李应卫，周锡龙，李法新^*。PZT压电陶瓷高温变形与失效的实验研究，实验力学,2012,27(5):527-534

120. 方岱宁, 毛贯中, 李法新, 冯雪, 万永平, 李长青, 江冰, 刘彬, 邴岐大, 功能材料的力、电、磁耦合行为的实验研究, 机械强度, 27(2): 217-226, 2005

121. 康海贵，李法新，翟钢军，近海导管架平台的选型模糊优化，中国海洋平台，15(6): 10-16, 2000