1.  Wang, X.L. & Lu, T.J., “Optimized acoustic properties of cellular solids”, J. Acous. Soc. Am. 106, 756-765, 1999.

2. Lu, T.J., Hess, A. & Ashby, M.F., “Sound absorption in metallic foams”, J. Applied Physics85, 7528-7539, 1999.

3. Lu, T.J., Chen, F. & He, D.P., “Sound absorption of cellular metals with semiopen cells”, J. Acous. Soc. Am. 108, 1697-1709, 2000.

4.  Wang, J., Lu, T.J., Woodhouse, J. & Langley, R.S., “Sound transmission through lightweight double-leaf partitions: theoretical modeling”, J. Sound and Vibration286, 817-847, 2005.

5. 卢天健，Dupere, I.D.J.，Dowling, A.P. “多孔泡沫材料的声吸收特性”，《西安交通大学学报》，2007，41(9): 1003-1011。

6.  Dupere, I.D.J.,卢天健，Dowling, A.P. “声学多孔材料的孔结构优化”,《西安交通大学学报》，2007，41(11): 1251-1256。

7.  Zhou, X.M., Hu, G.K. & Lu, T.J., “Elastic wave transparency of a coated sphere with metamaterials”, Phys. Review B, 2008, 77: 024101.

8.  Xin, F.X, Lu, T.J. & Chen, C., "Sound transmission through lightweight all-metallic sandwich panels with corrugated cores," Adv. Mater. Research 47-50, 57-60, 2008.

9. Lu, T.J., Kepets, M. & Dowling, A.P., “Acoustics properties of sintered FeCrAlY foams with open cells: I. Static flow resistance” (Invited contribution), Science in China: E – Tech Sci51(11), 1803-1811, 2008

10. Lu, T.J., Kepets, M. & Dowling, A.P., “Acoustic properties of sintered FeCrAlY foams with open cells: II. Sound attenuation” (Invited contribution), Science in China: E – Tech Sci51(11), 1812-1837, 2008

11.  Xin, F.X, Lu, T.J. & Chen, C., “Vibroacoustic behavior of clamp mounted double-panel partition with enclosure air cavity”, J. Acous. Soc. Am.124, 3604-3612, 2008.

12.  Xin, F.X & Lu, T.J., “Analytical and experimental investigation on transmission loss of clamped double panels: Implication of boundary effects”, J. Acous. Soc. Am. 125 (3), 1506-1517, 2009.

13. 辛锋先，卢天健，陈常青，“轻质金属三明治板的隔声性能研究”，《声学学报》，33(4), 340-347, 2008。 

14. 卢天健，高国钦，马守林，金峰，金东范， “二维四方排列半圆铝管/空气声子晶体的禁带特性”，《中国科学E辑》，39(1), 57-64, 2009。

15. Lu, T.J., Gao, G.Q., Ma, S.L., Jin, F. & Kim, T., “Acoustic band gaps in two-dimensional square arrays of semi-hollow circular cylinders”, Science in China: E – Tech Sci 52(2): 303-312, 2009.

16.  Xin, F.X, Lu, T.J. & Chen, C., “Sound transmission across lightweight all-metallic sandwich panels with corrugated cores”, Chinese J. Acous.28 (3), 231-243, 2009.

17.  Xin, F.X, Lu, T.J. & Chen, C., “External mean flow influence on noise transmission through double-leaf aeroelastic plates”, AIAA J.47(8), 1939-1951, 2009.

18.  Xin, F.X, Lu, T.J. & Chen, C., “Dynamic response and acoustic radiation of double-leaf aluminum panel partition under sound excitation”, Comput. Mater. Sci.46, 728-732, 2009.

19.  Xin, F.X, Lu, T.J. & Chen, C., “Sound transmission through simply supported finite double-panel partitions with enclosed air cavity”, ASME J. Vib. Acous.132(1), 011008, 2010.

20.  Xin, F.X & Lu, T.J., "Analytical modeling of fluid loaded orthogonally rib-stiffened sandwich structures: Sound transmission," J. Mech. Phys. Solids58, 1374-1396, 2010.

21.  Xin, F.X & Lu, T.J., "Analytical modeling of sound transmission from simply supported rectangular panel in convected fluids”, J. Acous. Soc. Am.128(3), 1087-1107, 2010.

22.  Xin, F.X & Lu, T.J., "Sound radiation of orthogonally rib-stiffened sandwich structures with cavity absorption”, Compos. Sci. Tech.70(15), 2198-2206, 2010.

23. 高国钦，马守林，金峰，金东范，卢天健，“声波在二维固/流声子晶体中的禁带特性研究”，《物理学报》，59(1), 393-400, 2010。（Gao, G.Q., Ma, S.L., Jin, F., Kim, T. & Lu, T.J., “Acoustic band gaps in finite-sized two-dimensional solid/fluid phononic crystals”, Acta Physica Sinica59(1), 393-400, 2010）

24. 辛锋先，张钱城，卢天健，“轻质三明治材料及结构的振动和声学性能研究进展”（特邀稿件），《力学进展》，40(4): 375-399, 2010。

25. 沈承，金峰，辛锋先，卢天健，“对边简支三明治加筋板的隔声性能研究”，《西安交通大学学报》，45(7): 1-10, 2011。

26.  Xin, F.X & Lu, T.J., "Transmission loss of orthogonally rib-stiffened double-panel structures with cavity absorption”, J. Acous. Soc. Am.129(4), 1919-1934, 2011.

27.  Xin, F.X & Lu, T.J., "Analytical modeling of wave propagation in orthogonally rib-stiffened sandwich structures: Sound radiation," Computers and Structures89(5-6), 507-516, 2011.

28.  Xin, F.X & Lu, T.J., "Analytical modeling of sound transmission through clamped triple-panel partition separated by enclosed air cavities," European J. Mechanics – A/Solids 30, 2011, 770-782.

29.  Xin, F.X & Lu, T.J., "Sound radiation of parallelly stiffened plates under convected harmonic pressure excitation," Science in China E: Technical Sciences 55(2), 496-500, 2012.

30.  Meng, H., Xin, F.X & Lu, T.J., “External mean flow effects on sound transmission through double-leaf plates filled with porous materials”, AIAA J. 50(10), 2268-2276, 2012.

31.  Shen, C., Xin, F.X & Lu, T.J., "Theoretical model for sound transmission through finite sandwich structures with corrugated core”, Int. J. Non-Linear Mechanics42, 1066-1072, 2012.

32.  Shen, C., Xin, F.X, Cheng, L. & Lu, T.J., "Sound radiation of orthogonally stiffened laminated composite plates under transverse and in plane excitation”, Comp. Sci. Tech. 84, 51-57, 2013.

33.  Xin, F.X & Lu, T.J., "Effects of mean flow on transmission loss of orthogonally rib-stiffened aeroelastic plate”, J. Acous. Soc. Am.133(6), 3909-3920, 2013.

34.  Xin, F.X & Lu, T.J., “External mean flow effects on noise radiation from orthogonally rib-stiffened aeroelastic plates”, AIAA J. 51(2): 406-415, 2013.

35. 任树伟，辛锋先，卢天健，“蜂窝层芯夹层板结构振动与传声特性研究”，《力学学报》 45(3)，349-358, 2013。

36.  Shen, C., Xin, F.X & Lu, T.J., “A 3-D elasticity theory based model for acoustic radiation from multilayered anisotropic plates”, J. Acous. Soc. Am.135(5), EL232-EL238, 2014.

37.  Meng, H., Xin, F.X & Lu, T.J., “Sound absorption optimization of graded semi-open cellular metals by adopting the genetic algorithm method”, ASME J. Vib. Acous. 136(6), 061007, 2014.

38.  Meng, H., Ao, Q.B., Tang, H.P., Xin, F.X & Lu, T.J., “Dynamic flow resistivity based model for sound absorption of multi-layer sintered fibrous metals”, Sci. in China - Technol. Sci. 57(11), 2096-2105, 2014.

39.  Xin, F.X & Lu, T.J., "Effects of core topology on sound insulation performance of lightweight all-metallic sandwich panels," Materials and Manufacturing Process (special issue "Multi-functional Materials"), 2014, doi: 10.1080/10426914.2010.531241.

40. 孟晗，卢天健，辛锋先，“多孔纤维吸声材料填充蜂窝结构的声学性能”，《中国科学E辑》 44(6)，599-609，2014。

41. 任树伟，辛锋先，卢天健，“考虑尺度效应的微平板声振耦合特性研究”，《中国科学E辑》 44(2)，201-208，2014。

42. 辛锋先，卢天健， “轻质板壳结构振动与声学耦合特性的理论及实验研究”，《应用数学和力学》35(6), 1-7, 2014.

43. 宁景锋，赵桂平，穆林，卢天健，“含有空气背衬层的分层多孔材料的吸声性能研究”，《振动工程学报》27(5)，734-740, 2014。

44. 任树伟，孟晗，辛锋先，张钱城，卢天健，慈军，耿丽，“方形蜂窝夹层曲板的振动特性研究”，《西安交通大学学报》49(3), 129-135, 2015。

45.  Ren, S.W., Meng, H., Xin, F.X. & Lu, T.J., “Sound absorption enhancement by thin multi-slit hybrid structures”, Chin. Phys. Lett. 32(1), 2015, 014302.

46.  Meng, H., Ao, Q.B., Ren, S.W., Xin, F.X., Tang, H.P. & Lu, T.J., “Anisotropic acoustical properties of sintered fibrous metals”, Comp. Sci. Tech. 107, 10-17, 2015.

47.  Shen, C., Xin, F.X & Lu, T.J., “Transmission loss of orthogonally stiffened composite laminates”, Int. J. Mech. Sci. Tech. 29(1), 59-66, 2015.

48.  Yang, X.H., Ren, S.W., Wang, W.B., Liu, X. & Lu, T.J., “A simplistic analytical model for sound adsorption of cellular foams with fully/semi-open cells”, Comp. Sci. Tech. 118, 276-283, 2015.

49.  Re, S.W., Meng, H., Xin, F.X & Lu, T.J., “Ultrathin multi-slit metamaterial as excellent sound absorber: Influence of micro-structure”, J. Appl. Phys.119(1), 014901, 2016.

50.  Shen, C., Xin, F.X & Lu, T.J., “Sound transmission across composite laminate sandwiches: influence of orthogonal stiffeners and laminate layup”, Comp. Struc. 143, 310-316, 2016.

51.  Meng, H., Xin, F.X & Lu, T.J., “Sound absorption optimization of gradient sintered metal fiber felts”, Sci. in China - Technol. Sci. 59(5), 699-708, 2016.

52.  Meng, H., Yang, X.H., Ren, S.W., Xin, F.X & Lu, T.J., “Sound propagation in composite micro-tubes with surface- mounted fibrous roughness elements”, Comp. Sci. Tech. 127, 158-168, 2016.

53.  Xin, F.X & Lu, T.J., “Tensional acoustomechanical soft metamaterials”, Scientific Reports 6, 27432, 2016.

54.  Xin, F.X & Lu, T.J., “Acoustomechanics of semicrystalline polymers”, Theor. Appl. Mech. Lett. 6(1), 38-41, 2016

55.  Xin, F.X & Lu, T.J., “Generalized method to analyze acoustomechanical stability of soft materials”, ASME J. Appl. Mech. 83(7), 071004, 2016.

56.  Xin, F.X & Lu, T.J., “Acoustomechanical soft elastomers with interpenetrating networks”, Smart Mater. Struc. 25(7),07LT02, 2016.

57.  Chen, W.H., Chen, T.N., Xin, F.X, Wang, X.P., Du, X.W. & Lu, T.J., “Modeling of sound absorption based on the fractal microstructures of porous fibrous metals”, Mater. Design 105, 386-397, 2016.

58.  Xin, F.X & Lu, T.J., “True method to analyze electromechanical stability of dielectric elastomers”, Europhys. Lett. (EPL) 114(2), 26002, 2016.

59.  Xin, F.X & Lu, T.J., “Acoustomechanical constitutive theory of soft materials”, Acta Mech. Sinica 32(5), 828-840, 2016.  

60.  Xin, F.X., Jiang, C.Y., Lu, T.J. & Huang, L.X., “Equivalent gradient properties of porous material with macro void structures”, J. Acous. Soc. Am.140(4), 2016.

61. 叶昌铮，孟晗，辛锋先，卢天健，“基于传递函数法的水下消声层声学性能研究”，《力学学报》 48(1)， 213-224, 2016。

62. 唐宇帆，任树伟，辛锋先，卢天健，“MEMS系统中微平板结构声振耦合性能研究”，《力学学报》 48(4)，907-916，2016。

63.  Xin, F.X & Lu, T.J., “A nonlinear acoustomechanical field theory of polymeric gels”, Int. J. Solids Struc. 112, 133-142, 2017.

64.  Xin, F.X & Lu, T.J., “A plane strain elasticity model for the acoustical properties of rib-stiffened composite plates”,European Journal of Mechanics A Solids 62, 1-13, 2017.

65.  Xin, F.X, Gong, J.Q., Ren, S.W. & Lu, T.J., “Thermoacoustic response of a simply supported isotropic rectangular plate in graded thermal environments”, Applied Mathematical Modeling 44, 456-469, 2017.

66.  Xin, F.X & Lu, T.J., “Nonlinear large deformation of acoustomechanical soft materials”, Mech. Mater. 107, 71-80, 2017.

67.  Xin, F.X., Jiang, C.Y., Lu, T.J.& Huang, L.X., “Equivalent gradient properties of porous material with macro void and panel structures”, J. Acous. Soc. Am. 140(4), 2993-2999, 2017.

68.  Tang, Y.F., Reng, S.W., Meng, H., Xin, F.X., Huang, L.X. & Lu, T.J., “Hybrid acoustic metamaterial as super absorber for broadband low-frequency sound”, Scientific Reports 7, 43340, 2017.

69.  Song, S.Y., Yang, X.H., Xin, F.X., Reng, S.W. & Lu, T.J., “Modeling of roughness effects on acoustic properties of micro-slits”, Journal of Physics D: Applied Physics 50(23), 235303, 2017.

70.  Reng, S.W., Ao, Q.B., Meng, H., Xin, F.X. & Lu, T.J., “A semi-analytical model for sound propagation in sintered fiber metal materials”, Composites B 126, 17-26, 2017.

71.  Xin, F.X & Lu, T.J., “Self-controlled wave propagation in hyperelastic media”, Scientific Reports 7, 7581, 2017.

72.  Peng, X.J., He, W., Liu, Y.F., Xin, F.X & Lu, T.J., “Optomechanical soft metamaterials”, Acta Mech. Sinica 33(3), 575-584, 2017.

73.  Meng, H., Galland, M.A., Ichchou, M., Xin, F.X. & Lu, T.J., “Small perforations in corrugated sandwich panel significantly enhance low frequency sound absorption and transmission loss”, Comp. Struc. 182, 1-11, 2017.

74.  Reng, S.W., Liu, X.W., Gong, J.Q., Tang, Y.F., Xin, F.X. & Lu, T.J., “Tunable acoustic absorbers with periodical micro-perforations having varying pore shapes”, Europhys. Lett. (EPL) 120(4), 44001, 2017.

75.  Cai, X.B., Hu, G.K., Lu, T.J. and Yang, J., “Sound absorption by acoustic metamaterials with optimized pore configuration”, J. Acous. Soc. Am. 144(2), EL138-EL143, 2017.

76.  Reng, S.W., Xin, F.X., Lu, T.J. & Zhang, C.Z., “A semi-analytical model for the influence of temperature on sound propagation in sintered metal fiber materials”, Mater. Design, 2017, 134: 513-522.

77.  Tang, Y.F., Xin, F.X., Huang, L.X. & Lu, T.J., “Deep subwavelength acoustic metamaterial for low-frequency sound absorption”, Europhys. Lett. (EPL), 2017, 118(4): 44002.

78.  Xin, F.X & Lu, T.J., “Generalized electromechanical stability of dielectric elastomers”, 2017.

79.  Song, S.Y., Yang, X.H., Xin, F.X. & Lu, T.J., “Modeling of surface roughness effects on stokes flow in circular pipes”, PHYSICS OF FLUIDS30, 023604 (2018).

80.  Xin, F.X & Lu, T.J., “Nonlinear acousto-thermo-mechanical deformation of hydrogels coupled with chemical diffusion”, Physical and Engineering Sciences, 2018, 474(2217): 20180293.

81.  Ye, C.Z., Liu, X.W., Xin, F.X. & Lu, T.J., “Influence of hole shape on sound absorption of underwater anechoic layers”, J Sound Vib. 426, 54-74, 2018.

82.  Xin, F.X & Lu, T.J., “Acousto-thermo-mechanical deformation of hydrogels coupled with chemical diffusion”, Proc. Roy. Soc. A474(2217), 20180293, 2018.

83. 张俊，陈卫华，任树伟，辛锋先，陈天宁，卢天健，“高温环境下梯度烧结金属纤维吸声性能及其结构优化研究”，《西安交通大学学报》52, 143-150, 2018。

84. 徐志敏，宋思远，辛锋先，杨肖虎，卢天健，“小Reynolds数下粗糙圆管中黏性流场的理论解”，《应用数学与力学》39(2), 123-136, 2018。

85.  Xin, F.X & Lu, T.J., “Modulation of acoustomechanical instability and bifurcation behavior of soft materials”, Scientific Reports 8(1), 2018.

86.  Reng, S.W., Belle, L.V., Claeys, C. F., Xin, F.X., Lu, T.J., Deckers, E., Desmet, W., “Improvement of sound absorption of flexible micro-perforated panels by local resonance”, Mechanical Systems and Signal Processing 117, 138-156, 2019.

87.  Xu, Z.M., Song, S.Y., Xin, F.X. & Lu, T.J., “Mathematical modeling of Stokes flow in petal shaped pipes”, PHYSICS OF FLUIDS 31(1), 013602, 2019.

88.  Ye, C.Z., Liu, X.W., Xin, F.X. & Lu, T.J., “Underwater acoustic absorption of composite anechoic layers with inner holes”, J Vib. Acoust., 1-22, 2019.

89. 张丰辉，唐宇帆，辛锋先，卢天健，“微穿孔蜂窝-波纹复合超材料吸声行为”，《物理学报》，2019，已录用。

90.  Xu, Z.M., Peng, X.J., Xin, F.X. & Lu, T.J., “Modified theory of microperforated panel with roughened perforations”, Europhys. Lett. (EPL), 2019, 125(3): 34004.

91.  Xu, Z.M., Xin, F.X. & Lu, T.J., “Dynamic capillary rise in rough tubes”, J. Colloid & Interface Science, 2018, submitted.

92.  Ren, S., Van Belle, L., Claeys, C., Xin, F. X., Lu, T.J., Deckers, E., Desmet, W. J. M. S. & Processing S., "Improvement of the sound absorption of flexible micro-perforated panels by local resonances," Mechanical Systems and Signal Processing. 117, 138-156, 2019.

93.  Ye, C., Liu, X., Xin, F. & Lu, T.J., "Underwater acoustic absorption of composite anechoic layers with inner holes," Journal of Vibration and Acoustics. 114, 1–22, 2019.

94.  Meng, H., Galland, M.A., Ichchou, M., Xin, F.X. & Lu, T.J., "On the low frequency acoustic properties of novel multifunctional honeycomb sandwich panels with micro-perforated faceplates," Applied Acoustics. 152, 31–40, 2019.

95.  Tang, Y., Xin, F. & Lu, T.J., "Sound absorption of micro-perforated sandwich panel with honeycomb-corrugation hybrid core at high temperatures," Composite Structures. 226, 111285, 2019.

96.  Xu, Z., Song, S., Xin, F. & Lu, T.J., "Mathematical modeling of Stokes flow in petal shaped pipes," Physics of Fluids. 31, 013602, 2019.

97.  Duan, M., Yu, C., Xu, Z., Xin, F. & Lu, T.J., "Acoustic impedance regulation of Helmholtz resonators for perfect sound absorption via roughened embedded necks," Appl. Phys. Lett. 117, 151904, 2020.

98.  Tang, Y., He, W., Xin, F. & Lu, T.J., "Nonlinear sound absorption of ultralight hybrid-cored sandwich panels," Mechanical Systems and Signal Processing. 135, 106428, 2020.

99.  Xu, Z., He, W., Peng, X., Xin, F. & Lu, T.J., "Sound absorption theory for micro-perforated panel with petal-shaped perforations," The Journal of the Acoustical Society of America. 148, 18–24, 2020.

100.  Xu, Z., He, W., Xin, F. & Lu, T.J., "Sound propagation in porous materials containing rough tubes," Physics of Fluids. 32, 093604, 2020.

101.  Peng, X., He, W., Xin, F., Genin, G. M., & Lu, T. J., “The acoustic radiation force of a focused ultrasound beam on a suspended eukaryotic cell”, Ultrasonics. 108, 106205, 2020.

102.  Peng, X., He, W., Xin, F., Genin, G. M., & Lu, T. J., “Standing surface acoustic waves, and the mechanics of acoustic tweezer manipulation of eukaryotic cells”, Journal of the Mechanics and Physics of Solids. 145, 104134, 2020.

103.  He, W., Peng, X., Xin, F. & Lu, T.J., "Ultralight micro-perforated sandwich panel with hierarchical honeycomb core for sound absorption," Jnl of Sandwich Structures & Materials. 1099636221993880, 2021.

104.  Duan, M., Yu, C., Xin, F. & Lu, T.J., "Tunable underwater acoustic metamaterials via quasi-Helmholtz resonance: From low-frequency to ultra-broadband," Applied Physics Letters. 118, 071904, 2021.

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