辛鋒先

辛鋒先,西安交通大學,航天航空學院/機械結構強度與振動國家重點實驗室,教授,博士生導師。

基本介紹

  • 中文名:辛鋒先
  • 民族:漢
  • 畢業院校:西安交通大學
  • 出生地:山東濟南
  • 代表作品:固體JMPS、流體JFM、聲學JASA、航空航天AIAA、機械工程MSSP、複合材料CST等各專業領域頂刊SCI論文100餘篇。
  • 職稱:教授
個人簡介,教育經歷,工作經歷,研究領域,講授課程,獨立文章,期刊文章,學術專著,

個人簡介

辛鋒先,男,固體力學博士,教授,博士生導師,青年拔尖人才計畫,陝西省傑青,哈佛大學訪問學者,MIT訪問學者。研究方向為聲波波動力學,主要研究軟介質多場耦合力學、多孔介質減振降噪、水聲材料多功能設計等,研究涉及固體力學、流體力學、聲學、傳熱學等多學科理論深度交叉領域。主持基金委國際合作、面上、聯合及國家基礎加強等多個國家項目,入選西安交通大學青拔人才計畫及青年教師跟蹤支持計畫,作為學術骨幹參加國家基礎研究計畫973項目和國家自然科學基金創新群體項目。在固體力學JMPS、流體力學JFM、聲學JASA、航空航天AIAA、機械工程MSSP、複合材料CST等專業領域頂刊發表SCI論文100餘篇(其中第一/通訊SCI論文90餘篇),合作出版學術專著2部,申報/授權發明專利50餘項。研究工作獲得25位中外科學院院士/工程院院士及幾十位國際學會Fellow的高度認可與正面積極評價,套用技術成果獲得型號裝備套用。擔任國家自然科學基金委數理學部、工材學部青、地、面及優青等項目評審專家。擔任2個SCI國際學術期刊編委,2021年入選“全球前2%頂尖科學家榜單”,2022年入選Elsevier“中國高被引學者”榜單,獲得全國百篇優秀博士論文提名獎、中國科協優秀科技論文獎、國際先進材料協會IAAM Scientist Medal、江蘇省力學學會科學技術獎和中國機械工業科學技術獎等。

教育經歷

· 2006/09-2011/03,西安交通大學,固體力學,研究生/工學博士
· 2002/09-2006/07,西安交通大學,工程力學,本科/工學學士

工作經歷

2020.12.14-至今,西安交通大學,航天航空學院,教授,博士生導師
2016.01-2020.12,西安交通大學,航天航空學院,副教授,博士生導師
2017.10-2017.11,美國麻省理工學院機械工程系,訪問學者
2015.01-2016.01,美國哈佛大學工程與套用科學學院,訪問學者
2014.01-2014.12,西安交通大學,航天航空學院,副教授 博士生導師
2011.04-2013.12,西安交通大學航天航空學院,講師,碩士生導師

研究領域

1. 固體力學
2. 前沿與交叉力學
3. 聲波波動力學
4. 軟介質多場耦合力學
5. 多孔介質減振降噪機理
6. 水聲材料結構多功能設計
7. 超材料/超結構波動力學
8. 3D列印超材料波動力學設計
9. 細胞及生物組織力學
10. 微通道流體力學
11. 多功能複合材料結構設計
12. 超材料設計、性能表征及套用
主要研究聲波波動力學,立足於固體力學,研究涉及流體力學、聲學、傳熱學等多學科交叉領域。

講授課程

本科生課程《工程力學》
本科生課程《結構設計原理及最佳化設計》
研究生課程 《聲學理論與工程套用

獨立文章

  1. Liu YF, Xin FX. Shape dynamics of capsules in two phase-shifted orthogonal ultrasonic standing waves: A numerical investigation. Journal of Fluid Mechanics, 2023, 964:A18:1-29.
  2. Liu XW, Liu ML, Xin FX. Sound absorption of a perforated panel backed with perforated porous material: Energy dissipation of Helmholtz resonator cavity. Mechanical Systems and Signal Processing, 2023, 185: 109762:1-14.
  3. Zhang WT, Liu XW, Xin FX. Normal incidence sound absorption of an acoustic labyrinthine metal-fibers-based porous metamaterial at high temperature. International Journal of Mechanical Sciences, 2023, 237: 107821:1-10.
  4. Liu YF, Xin FX. Nonlinear large deformation of a spherical red blood cell induced by ultrasonic standing waves. Biomechanics and Modeling in Mechanobiology, 2022, 21: 589-604.
  5. Liu YF, Xin FX. Characterization of red blood cell deformability induced by acoustic radiation force. Microfluidics and Nanofluidics, 2022, 26: 7:1-12.
  6. Ke LW, Xu ZM, Liu YF, Xin FX. Time-dependent deformation of biological tissue under ultrasonic irradiation. International Journal of Mechanical Sciences, 2022, 227: 107432: 1-8.
  7. Zhang L, Zhang WT, Xin FX. Sound absorption of two-dimensional rough tube porous materials. Physics of Fluids, 2022, 34(8): 083612:1-12. [PoF主編遴選Featured article].
  8. Zhang L, Xin FX. Perfect low-frequency sound absorption of rough neck embedded Helmholtz resonators. Journal of the Acoustical Society of America, 2022, 151(2): 1191-1199.
  9. Xin FX. Signal response of rib-stiffened plates covered by decoupling coating layers. Journal of Sound and Vibration, 2015, 348: 206-223.
  10. Xin FX, Ma XW, Liu XW, Zhang Ch. A multiscale theoretical approach for the sound absorption of slit-perforated double porosity materials. Composite Structures, 2019, 223: 110919:1-12.
  11. Xin FX. An exact elasticity model for rib-stiffened plates covered by decoupling acoustic coating layers. Composite Structures, 2015, 119(1): 559-567.
  12. Liu XW, Yu CL, Xin FX. Gradually perforated porous materials backed with Helmholtz resonant cavity for broadband low-frequency sound absorption. Composite Structures, 2021, 263: 113647:1-9.
  13. Liu XW, Ma XW, Yu CL, Xin FX. Sound absorption of porous materials perforated with holes having gradually varying radii. Aerospace Science and Technology, 2022, 120: 107229:1-16.
  14. Gong JQ, Xin FX. External mean flow effect on sound transmission through composite sandwich structures filled with porous materials. Applied Mathematical Modelling, 2022,101: 729-747.
  15. Liu YF, Xin FX. Nonlinear deformation and bifurcation of a soft cantilever induced by acoustic radiation force. Europhysics letters, 2019, 127(2): 24003:p1-p7.
  16. Zhou XD, Duan MY, Xin FX. Low-frequency underwater sound absorption of hybrid metasurface using dissipative slow-sound. Physics Letters A, 2022, 450: 128361:1-6.
  17. Liu XW, Duan MY, Liu ML, Xin FX, Zhang Ch. Acoustic labyrinthine porous metamaterials for subwavelength low-frequency sound absorption. Journal of Applied Physics, 2021, 129: 195103:1-8.
  18. Zhang WT, Liu XW, Xin FX. Sound absorption performance of helically perforated porous metamaterials at high temperature. Materials & Design, 2023, 225: 111437:1-10.
  19. Liu YF, Xin FX.Deformation dynamics of spherical red blood cells in viscous fluid driven byultrasound. Physics of Fluids, 2023, 35(1): 012011:1-13.
  20. Liu YF, Xin FX.Mechanics of biconcave red blood cells deformed by acoustic tweezers. Mechanics of Materials, 2023, 178: 104565: 1-11.
  21. Liu YF, Xin FX.Modeling of red blood cell deformation in a microchannel driven by travelingsurface acoustic waves. InternationalJournal of Solids and Structures, 2023,267: 112141:1-13.
  22. Zhang L, Zhang WT, XinFX. Broadband low-frequency sound absorption of honeycombsandwich panels with rough embedded necks. Mechanical Systemsand Signal Processing, 2023, 196: 110311:1-12.

期刊文章

  1. Liu YF, Xin FX. Shape dynamics of capsules in two phase-shifted orthogonal ultrasonic standing waves: A numerical investigation. Journal of Fluid Mechanics, 2023, 964:A18:1-29.
  2. Liu XW, Liu ML, Xin FX.Sound absorption of a perforated panel backed with perforated porous material: Energydissipation of Helmholtz resonator cavity. Mechanical Systems and Signal Processing,2023, 185: 109762:1-14.
  3. Zhang WT, Liu XW, Xin FX. Normalincidence sound absorption of an acoustic labyrinthine metal-fibers-basedporous metamaterial at high temperature. InternationalJournal of Mechanical Sciences, 2023, 237: 107821:1-10.
  4. Liu YF, Xin FX.Deformation dynamics of spherical red blood cells in viscous fluid driven byultrasound. Physics of Fluids, 2023, 35(1): 012011:1-13.
  5. Zhang L, Zhang WT, XinFX. Broadband low-frequency sound absorption of honeycombsandwich panels with rough embedded necks. Mechanical Systemsand Signal Processing, 2023, 196: 110311:1-12.
  6. Liu YF, Xin FX.Mechanics of biconcave red blood cells deformed by acoustic tweezers. Mechanics of Materials, 2023, 178: 104565: 1-11.
  7. Liu YF, Xin FX. Deformation dynamics of spherical red blood cells in viscous fluid driven by ultrasound. Physics of Fluids, 2023,35(1): 012011:1-13.
  8. Zhang WT, LiuXW, Xin FX. Sound absorption performance of helically perforated porous metamaterials at high temperature. Materials & Design, 2023, 225:111437:1-10.
  9. Liu YF, Xin FX.Nonlinear large deformation of a spherical red blood cell induced by ultrasonicstanding waves. Biomechanics and Modeling in Mechanobiology,2022, 21: 589-604.
  10. Liu YF, Xin FX. Characterization of red blood celldeformability induced by acoustic radiation force. Microfluidics and Nanofluidics, 2022, 26(1): 7:1-12.
  11. Ke LW, Xu ZM, Liu YF, Xin FX. Time-dependent deformation ofbiological tissue under ultrasonic irradiation. InternationalJournal of Mechanical Sciences, 2022, 227: 107432: 1-8.
  12. Zhang L, Xin FX. Perfect low-frequency sound absorptionof rough neck embedded Helmholtz resonators. Journalof the Acoustical Society of America, 2022, 151(2): 1191-1199.
  13. Gong JQ, Xin FX. Externalmean flow effect on sound transmission through composite sandwich structuresfilled with porous materials. Applied Mathematical Modelling, 2022,101:729-747.
  14. Liu XW, Ma XW, Yu CL, Xin FX. Soundabsorption of porous materials perforated with holes having gradually varyingradii. Aerospace Science and Technology, 2022,120: 107229:1-16.
  15. Zhang L, Zhang WT, Xin FX. Soundabsorption of two-dimensional rough tube porous materials. Physicsof Fluids, 2022, 34(8): 083612:1-12. [PoF主編遴選Featuredarticle].
  16. Zhou XD, Duan MY, Xin FX.Low-frequency underwater sound absorption of hybrid metasurface usingdissipative slow-sound. Physics Letters A,2022, 450:128361:1-6.
  17. He W, Peng XJ, Xin FX, Lu TJ. Ultralightmicro-perforated sandwich panel with hierarchical honeycomb core for soundabsorption. Journal of Sandwich Structures & Materials, 2022, 24(1): 201-217.
  18. Junzhe Zhang, Tianning Chen,Fengxian Xin, Jian Zhu,Wei Ding. New-parallel connection of the Helmholtz resonator with embeddedapertures for low-frequency broadband sound absorption. Japanese Journal of AppliedPhysics, 2022, 61: 077001:1-7.
  19. He W, Peng XJ, Xin FX, Lu TJ. Amicrostructure-based model of transport parameters and sound absorption forwoven fabrics. Composites Science and Technology, 2022, 227:109607:1-10.
  20. Xiangjun Peng, Yifan Liu, Wei He, Ethan D. Hoppe, Lihong Zhou,Fengxian Xin, Elizabeth Haswell, Barbara G. Pickard, Guy M. Geninand Tian Jian Lu. Acoustic radiation force on a long cylinder, andpotential sound transduction by tomato trichomes. BiophysicalJournal, 2022, 121: 3917-3926.
  21. Yu CL, Duan MY, He W, Chen X, XinFX, Lu TJ. Grating-like anechoic layer embeddedwith an air layer for broadband underwater sound absorption. InternationalJournal of Mechanical System Dynamics, 2022, 2: 265-277. [芮院士主編特邀文章]
  22. Liu XW, Xin FX,Zhang Ch. Erratum: “High-temperature effect on the sound absorptionof cylindrically perforated porous materials” [J. Appl. Phys. 130, 105101(2021)]. Journal of Applied Physics, 2022, 132(12): 129902.
  23. Liu XW, Yu CL,Xin FX. Graduallyperforated porous materials backed with Helmholtz resonant cavity for broadbandlow-frequency sound absorption. Composite Structures, 2021, 263: 113647:1-9.
  24. Duan MY, Yu CL, Xin FX, Lu TJ.Tunable underwater acoustic metamaterials via quasi-Helmholtz resonance: fromlow-frequency to ultra-broadband. Applied Physics Letters, 2021, 118: 071904:1-6.
  25. He W, Peng XJ,Chen X, Xin FX,Lu TJ. 3D mechanical analysis of a self-contractile cell with stress fibersreorganization. Applied Mathematical Modelling, 2021, 92: 710-718.
  26. Peng XJ, He W, Xin FX, Genin Guy M.,Lu TJ. Effects of coating on dynamic stress concentration in fiber reinforcedcomposites. International Journal of Solids and Structures, 2021,222-223: 111029: 1-14.
  27. Liu XW, Duan MY, Liu ML, Xin FX, Zhang Ch..Acoustic labyrinthine porous metamaterials for subwavelength low-frequencysound absorption. Journal of Applied Physics, 2021, 129:195103:1-8.
  28. Lei Jiechao, Xu ZM, Xin FX, Lu TJ.Dynamics of capillary flow in an undulated tube. Physics of Fluids, 2021, 33(5): 052109: 1-9.
  29. Yu CL, Duan MY, He W, Xin FX, Lu TJ.Underwater anechoic layer with parallel metallic plate insertions: theoreticalmodelling. Journal of Micromechanics and Microengineering, 2021, 31:074002: 1-11.
  30. Qihang Liu; Xuewei Liu, ChuanzengZhang, Fengxian Xin.High-temperature and low-frequency acoustic energy absorption by a novel porousmetamaterial structure. Acta Mechanica Solida Sinica, 2021, 34(4):1-12.
  31. He W, Liu ML, Peng XJ, Xin FX, Lu TJ.Sound absorption of petal shaped micro-channel porous materials. Physicsof Fluids, 2021, 33: 063606:1-8.
  32. Qihang Liu, Xuewei Liu, Chuanzeng Zhang,Fengxian Xin. A novelmultiscale porous composite structure for sound absorption enhancement. CompositeStructures, 2021, 276: 114456: 1-16.
  33. Kang R, Xin FX, Shen C, Lu TJ. 3D free vibrationanalysis of functionally graded plates with arbitrary boundary conditions in thermalenvironment. Advanced Engineering Materials,2021, 2100636: 1-16.
  34. Liu XW, Xin FX, Zhang Ch. High-temperatureeffect on the sound absorption of cylindrically perforated porous materials. Journalof Applied Physics, 2021, 130(10): 105101:1-11.
  35. Duan MY, Yu CL, He W, Xin FX, Lu TJ.Perfect sound absorption of Helmholtz resonators withembedded channels in petal shape. Journal of Applied Physics, 2021, 130(13): 135102:1-8.
  36. Tang YF, He W,Xin FX, Lu TJ.Nonlinear sound absorption of ultralight hybrid-cored sandwich panels. MechanicalSystems and Signal Processing, 2020, 135:106428:1-11.
  37. Xu ZM, He W, Peng XJ, Xin FX, Lu TJ. Soundabsorption theory for micro-perforated panel with petal-shaped perforations. Journalof the Acoustical Society of America, 2020, 148(1):18-24.
  38. Peng XJ, He W, Xin FX, Genin Guy M.,Lu TJ. The acoustic radiation force of a focused ultrasound beam ona suspended eukaryotic cell. Ultrasonics, 2020, 108: 106205: 1-10.
  39. Xu ZM, He W, Xin FX, Lu TJ.Sound propagation in porous materials containing rough tubes. Physicsof Fluids, 2020, 32(9):093604:1-9.[PoF主編遴選Editor's Pick].
  40. Peng XJ, He W, Xin FX, Guy M. Genin,Lu TJ. Standing surface acoustic waves, and the mechanics ofacoustic tweezer manipulation of eukaryotic cells. Journal of the Mechanics andPhysics of Solids, 2020, 145:104134:1-14.
  41. Duan MY, Yu CL, Xu ZM, Xin FX, Lu TJ.Acoustic impedance regulation of Helmholtz resonators for perfect soundabsorption via roughened embedded necks. Applied Physics Letters, 2020, 117(15): 151904:1-5.
  42. Xin FX, Ma XW, LiuXW, Zhang Ch. A multiscale theoretical approach for the sound absorption ofslit-perforated double porosity materials. Composite Structures, 2019, 223: 110919:1-12.
  43. S. W. Ren,L. Van Belle, C. Claeys, F. X. Xin*,T. J. Lu, E. Deckers, W. Desmet. Improvement of the soundabsorption of flexible micro-perforated panels by local resonances. MechanicalSystems and Signal Processing, 2019, 117: 138-156.
  44. Xu ZM, Song SY, Xin FX, Lu TJ.Mathematical modeling of Stokes flow in petal shaped pipes. Physicsof Fluids, 2019, 31(1): 013602: 1-9. [PoF主編遴選Featured article].
  45. Meng H., Galland M.A.,Ichchou M., Xin F.X., and Lu T.J. On the low frequency acousticproperties of novel multifunctional honeycomb sandwich panels withmicro-perforated faceplates. Applied Acoustics, 2019, 152:31-40.
  46. Xu ZM, Peng XJ, Liu XW, Xin FX, Lu TJ.Modified theory of a microperforated panel with roughened perforations. Europhysicsletters, 2019, 125: 34004:p1-p6.
  47. Ye CZ, Liu XW,Xin FX, Lu TJ. Underwateracoustic absorption of composite anechoic layers with inner holes. Journalof Vibration and Acoustics-ASME, 2019, 141(4):041006:1-9.
  48. Liu YF, Xin FX. Nonlineardeformation and bifurcation of a soft cantilever induced by acoustic radiationforce. Europhysics letters, 2019, 127(2): 24003:p1-p7.
  49. Tang YF, Xin FX, Lu TJ.Sound absorption of micro-perforated sandwich panel with honeycomb-corrugationhybrid core at high temperatures. Composite Structures, 2019, 226: 111285:1-11.
  50. Song SY, YangXH, Xin FX, Lu TJ.Modeling of surface roughness effects on Stokes flow in circular pipes. Physicsof Fluids, 2018, 30(2): 023604:1-11.
  51. Song SY, Yang XH, Xin FX, Lu TJ.Publisher’s Note: “Modeling of surface roughness effects on Stokes flow incircular pipes” [Phys. Fluids 30, 023604 (2018)]. Physics of Fluids, 2018,30(4): 049901.
  52. Ye CZ, Liu XW, Xin FX, Lu TJ.Influence of hole shape on sound absorption of underwater anechoic layers. Journalof Sound and Vibration, 2018, 426: 54-74.
  53. Xin FX, Lu TJ.Acousto-thermo-mechanical deformation of hydrogels coupled with chemicaldiffusion. Proceedings of the Royal Society A: Mathematical, Physical andEngineering Sciences, 2018, 474(2217): 20180293:1-17.
  54. Zhang FH, Tang YF, Xin FX, Lu TJ.Micro-perforated acoustic metamaterial with honeycomb-corrugation hybrid corefor broadband low frequency sound absorption. Acta Physics Sinica, 2018,67:234303:1-11.
  55. Xin FX, Lu TJ. Modulation ofacoustomechanical instability and bifurcation behavior of soft material. ScientificReports, 2018, 8(1), 16661:1-10.
  56. Xin FX, Lu TJ.A plane strain elasticity model for the acoustical properties of rib-stiffenedcomposite plates. European Journal of Mechanics - A/Solids, 2017, 62: 1-13.
  57. Tang Y, Ren SW, Meng H, Xin FX, Huang LX,Chen TN, Zhang Ch, Lu TJ. Hybrid acoustic metamaterial as superabsorber for broadband low-frequency sound. Scientific Reports,2017,7:43340:1-10.
  58. Xin FX, Lu TJ.Nonlinear large deformation of acoustomechanical soft materials. Mechanicsof Materials, 2017,107:71-80.
  59. Xin FX, Gong JQ, Ren SW, Huang LX,Lu TJ. Thermoacoustic response of a simply supported isotropic rectangularplate in graded thermal environments. Applied Mathematical Modelling, 2017,44: 456-469.
  60. Xin FX, Lu TJ. Anonlinear acoustomechanical field theory of polymeric gels. InternationalJournal of Solids and Structures, 2017, 112: 133-142.
  61. Peng XJ, He W, Liu YF, Xin FX, Lu TJ.Optomechanical Soft Metamaterials. Acta Mechanica Sinica, 2017, 33(3),575-584.
  62. Song SY, Yang XH,Xin FX, Ren SW, LuTJ. Modeling of roughness effects on acoustic properties of micro-slits.Journalof Physics D: Applied Physics, 2017, 50(23): 235303:1-14.
  63. Ren SW, Ao QB, Meng H, Xin FX, Huang LX,Zhang Ch, Lu TJ. A semi-analytical model for sound propagation insintered fiber metals. Composites Part B-Engineering, 2017,126: 17-26.
  64. Tang YF, Xin FX, Huang LX, LuTJ. Deep subwavelength acoustic metamaterial for low-frequencysound absorption. Europhysics letters, 2017, 118(4): 44002:p1-p5.
  65. Xin FX, Lu TJ.Self-controlled wave propagation in hyperelastic media. ScientificReports, 2017,7(1): 7581:1-9.
  66. Ren SW, Xin FX, Lu TJ,Zhang Ch. A semi-analytical model for the influence of temperature on soundpropagation in sintered metal fiber materials. Materials & Design, 2017,134: 513-522.
  67. Tang YF, Li FH, Xin FX, Lu TJ.Heterogeneously perforated honeycomb-corrugation hybrid sandwich panel as soundabsorber. Materials & Design, 2017, 134: 502-512.
  68. Han Meng, GallandMarie-Annick, Olivier Bareille, Fengxian Xin, Tian Jian Lu. Small perforations in corrugatedsandwich panel significantly enhance low frequency sound absorption andtransmission loss. Composite Structures, 2017, 182:1-11.
  69. Ren SW, Liu XW, Gong JQ,Tang YF, Xin FX,Huang LX, Lu TJ. Tunable acoustic absorbers with periodical micro-perforationshaving varying pore shapes. Europhysics letters, 2017, 120(4):44001:p1-p6.
  70. Xin FX, Lu TJ.Analytical modeling of fluid loaded orthogonally rib-stiffened sandwichstructures: Sound transmission. Journal of the Mechanics and Physics ofSolids, 2010, 58 (9):1374-1396.
  71. Xin FX, Lu TJ. Soundradiation of orthogonally rib-stiffened sandwich structures with cavityabsorption. Composites Science and Technology, 2010, 70 (15): 2198-2206.
  72. Xin FX, Lu TJ. Analytical andexperimental investigation on transmission loss of clamped double panels:Implication of boundary effects. Journal of the Acoustical Society of America,2009, 125 (3): 1506-1517.
  73. Xin FX, Lu TJ, Chen CQ.Vibroacoustic behavior of clamp mounted double-panel partition with enclosureair cavity. Journal of the Acoustical Society of America, 2008, 124 (6):3604-3612.
  74. Xin FX, Lu TJ. Analyticalmodeling of sound transmission across finite aeroelastic panels in convectedfluids. Journal of the Acoustical Society of America, 2010, 128 (3):1097-1107.
  75. Xin FX, Lu TJ. Transmission lossof orthogonally rib-stiffened double-panel structures with cavity absorption. Journalof the Acoustical Society of America, 2011, 129 (4): 1919-1934.
  76. Xin FX, Lu TJ, Chen CQ. Dynamicresponse and acoustic radiation of double-leaf metallic panel partition undersound excitation. Computational Materials Science, 2009, 46 (3): 728-732.
  77. Xin FX, Lu TJ, ChenCQ. External mean flow Influence on noise transmission throughdouble-leaf aeroelastic plates. AIAA Journal, 2009, 47 (8):1939-1951.
  78. Xin FX, Lu TJ, ChenCQ. Sound Transmission through Simply Supported Finite Double-Panel Partitionswith Enclosed Air Cavity. Journal of Vibration and Acoustics-ASME,2010, 132 (1), 011008: 1-11.
  79. Xin FX, Lu TJ. Analyticalmodeling of sound transmission through clamped triple-panel partition separatedby enclosed air cavities. European Journal of Mechanics - A/Solids,2011, 30 (6): 770-782.
  80. Xin FX, Lu TJ. Analyticalmodeling of wave propagation in orthogonally rib-stiffened sandwich structures:Sound radiation. Computers and Structures, 2011, 89 (5-6): 507-516.
  81. Xin FX, Lu TJ. Effects of coretopology on sound insulation performance of lightweight all-metallic sandwichpanels. Materials and Manufacturing Processes, 2011, 26 (9): 1213-1221.
  82. Shen C, Xin FX, Lu TJ.Theoretical model for sound transmission through finite sandwich structureswith corrugated core. International Journal of Non-LinearMechanics, 2012, 47(10): 1066-1072.
  83. Xin FX, Lu TJ. Sound radiation ofparallelly stiffened plates under convected harmonic pressure excitation. ScienceChina Technological Sciences, 2012, 55(2): 496-500.
  84. Meng H, Xin FX and Lu TJ.External Mean Flow Effects on Sound Transmission Through Acoustic AbsorptiveSandwich Structure. AIAA Journal, 2012, 50(10): 2268-2276.
  85. Ni CY, Li YC, Xin FX, Jin F and LuTJ. Ballistic resistance of hybrid-cored sandwich plates: numericaland experimental assessment. Composites Part A: Applied Science andManufacturing, 2013, 46: 69-79.
  86. Xin FX, Lu TJ.External Mean Flow Effects on Noise Radiation from Orthogonally Rib-StiffenedAeroelastic Plates. AIAA Journal, 2013, 51(2): 406-415.
  87. Xin FX, Lu TJ. Effects of meanflow on transmission loss of orthogonally rib-stiffened aeroelastic plates. Journalof the Acoustical Society of America, 2013, 133(6): 3909-3920.
  88. Shen C, Xin FX, Cheng L, LuTJ. Sound radiation of orthogonally stiffened laminated compositeplates under airborne and structure borne excitations. Composites Science and Technology,2013, 84: 51-57.
  89. Shen C, Xin FX, Lu TJ. A 3-Delasticity theory based model for acoustic radiation from multilayeredanisotropic plates. Journal of the Acoustical Society of America, 2014, 135(5):EL232-EL238.
  90. Shen C, Xin FX, Lu TJ.Transmission Loss of Orthogonally Stiffened Laminated Composite Plates . Journalof Mechanical Science and Technology, 2015, 29(1):59-66.
  91. Meng H, Ao QB, Tang HP, Xin FX and Lu TJ.Dynamic flow resistivity based model for sound absorption of multi-layersintered fibrous metals. Science China Technological Sciences,2014, 57(11): 2096-2105.
  92. Meng H, Xin FX and Lu TJ.Sound absorption optimization of graded semi-open cellular metals by adoptingthe genetic algorithm method. Journal of Vibration and Acoustics-ASME,2014, 136(6), 061007:1-8.
  93. Xin FX. An exact elasticity modelfor rib-stiffened plates covered by decoupling acoustic coating layers. CompositeStructures, 2015, 119(1): 559-567.
  94. Ren SW, Meng H, Xin FX and Lu TJ.Sound absorption enhancement by thin multi-slit hybrid structures. ChinesePhysics Letters,2015, 32(1),014302: 1-4.
  95. Meng H, Ao QB, Ren SW, Xin FX, Tang HP and LuTJ. Anisotropic acoustical properties of sintered fibrous metals.Composites Science and Technology,2015, 107: 10-17.
  96. Xin FX. Signal response ofrib-stiffened plates covered by decoupling coating layers. Journal of Sound and Vibration,2015, 348: 206-223.
  97. Yang XH, Ren SW, Wang WB, LiuX, Xin FX, Lu TJ.A simplistic unit cell model for sound absorption of cellular foams with fully/semi-opencells. Composites Science and Technology,2015,118: 276-283.
  98. Ren SW, Meng H, Xin FX and Lu TJ.Ultrathin multi-slit metamaterial as excellent sound absorber: Influence ofmicro-structure. Journal of Applied Physics,2016, 119(1), 014901:1-8.
  99. Shen C, Xin FX, Lu TJ. Soundtransmission across composite laminate sandwiches: influence of orthogonalstiffeners and laminate layup. Composite Structures, 2016, 143,310-316.
  100. Meng H, Yang Xh, Ren SW, XinFX and Lu TJ.Sound propagation in composite micro-tubes with surface-mounted fibrousroughness elements. Composites Science and Technology,2016, 127, 158-168 .
  101. Meng H, RenSW, Xin FX and Lu TJ.Sound absorption coefficient optimization of gradient sintered metal fiberfelts. Science China Technological Sciences,2016, 59(5), 699-708.
  102. Xin FX, Lu TJ.Generalized method to analyze acoustomechanical stability of soft materials. Journalof Applied Mechanics-ASME, 2016, 83(7), 071004:1-4.
  103. Xin FX, Lu TJ.Acoustomechanical constitutive theory for soft materials. Acta Mechanica Sinica, 2016,32(5), 828-840. [第四屆中國科協優秀科技論文獎]
  104. Xin FX, Lu TJ. True method to analyzeelectromechanical stability of dielectric elastomers. Europhysics letters, 2016,114(2): 26002:p1-p5.
  105. Xin FX, Lu TJ.Tensional acoustomechanical soft metamaterials. Scientific Reports, 2016,6: 27432:1-7.
  106. Chen WH, Chen TN, Xin FX, Wang Xp, DuXW, Lu TJ. Modeling of sound absorption based on the fractal microstructures ofporous fibrous metals. Materials & Design, 2016, 105:386-397.
  107. Xin FX, Lu TJ.Acoustomechanical giant deformation of soft elastomers with interpenetratingnetworks. Smart Materials and Structures, 2016, 25(7): 07LT02:1-7.
  108. Ma XW, Liu XW, Xin FX. Soundabsorption performance of gradiently slit-perforated double porosity materials.ChineseJournal of Acoustics, 2021, 40(1): 1-17.
  109. Xin FX, Lu TJ, ChenCQ. Sound transmission across lightweight all-metallic sandwich panels withcorrugated cores. Chinese Journal of Acoustics, 2009, 28 (3): 231-243.
  110. Xin FX, Lu TJ.Acoustomechanics of semicrystalline polymers. Theoretical and Applied MechanicsLetters, 2016, 6(1): 38-41.
  111. 辛鋒先, 張錢城, 盧天健. 輕質夾層材料的製備和振動聲學性能. 力學進展, 2010, 40 (4): 375-399.
  112. 任樹偉, 辛鋒先, 盧天健. 蜂窩層芯夾層板結構振動與傳聲特性研究. 力學學報, 2013, 45(3): 349-358.
  113. 辛鋒先. 複雜板殼結構聲振耦合特性的理論與實驗研究. 固體力學學報, 2012, 33 (3):336-340.
  114. 孟晗, 辛鋒先, 盧天健. 多孔纖維吸聲材料填充蜂窩結構的聲學性能. 中國科學: 物理學 力學 天文學, 2014, 44(6): 599-609.
  115. 任樹偉, 辛鋒先, 盧天健. 考慮尺度效應的微平板聲振耦合特性研究. 中國科學: 技術科學, 2014, 44(2): 201-208.
  116. 辛鋒先, 盧天健. 輕質板殼結構振動與聲學耦合特性的理論及實驗研究. 套用數學和力學, 2014, 35(6): 1001-1007.
  117. 辛鋒先, 盧天健, 陳常青. 輕質金屬三明治板的隔聲性能研究. 聲學學報, 2008, 33 (4): 340-347.
  118. 任樹偉, 孟晗, 辛鋒先, 盧天健, 慈軍, 耿麗. 方形蜂窩夾層曲板的振動特性研究. 西安交通大學學報, 2015, 49(3): 129-135.
  119. 張俊, 陳衛華, 任樹偉, 辛鋒先, 陳天寧, 盧天健. 高溫環境下梯度多孔金屬纖維的吸聲性能及最佳化設計. 西安交通大學學報, 2018, 52(1): 143-150.
  120. 馬曉文, 劉學偉, 辛鋒先. 梯度穿縫型雙孔隙率多孔材料的吸聲性能. 聲學學報, 2020, 45(2): 247-257.
  121. 葉昌錚, 孟晗, 辛鋒先, 盧天健. 基於傳遞函式法的水下消聲層聲學性能研究. 力學學報, 2016, 48(1): 213-224.
  122. 唐宇帆, 任樹偉, 辛鋒先, 盧天健. MEMS系統中微平板結構聲振耦合性能研究. 力學學報, 2016, 48(4):907-916.
  123. 徐志敏, 宋思遠, 辛鋒先, 楊肖虎, 盧天健. 小Reynolds數下粗糙圓管中黏性流場的理論解. 套用數學與力學, 2018, 39(2): 123-136. [期刊當期置頂Hot文章!]

學術專著

  1. 盧天健, 辛鋒先. 輕質板殼結構設計的振動和聲學基礎(229 pages,288k). 北京: 科學出版社, 國家科學技術學術著作出版基金資助出版, 2012, ISBN978-7-03-030428-5.
  2. Lu TJ and Xin FX. Vibro-acoustics oflightweight sandwich structures (339 pages,443k). Berlin Heidelberg: Springer,2014, ISBN 978-3-642-55357-8.

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