师资队伍

教师名录

龚志雄

船舶与海洋工程系

电子邮件:zhixiong.gong@sjtu.edu.cn
通讯地址:上海交通大学闵行校区木兰船建大楼
个人主页:https://zhixionggong.github.io/AcousticsX.com/

副教授,博士生导师,国家级青年人才

工作经历:

  • 2022.12 - 至今                           上海交通大学                               长聘教轨副教授

  • 2018.12 - 2022.11                     法国国家科学研究中心(CNRS)         博士后(合作导师:Michael Baudoin、Jean-Louis Thomas)

  • 2016.12 - 2018.04                     美国华盛顿州立大学 (WSU)            访问学者(合作导师:Philip L. Marston)

教育经历:

  • 2013.09 - 2018.09                     华中科技大学        博士(指导导师:李威教授、赵耀教授)

  • 2009.09 - 2013.06                     华中科技大学        学士

  • * 物理声学

  • * 水声工程

  • * 声波操控微粒/微流体理论和技术

  • * 水下MEMS声学传感器


  • 硕博研究生

  • 李世玉 (联合指导博士生,研究方向:声波操控微粒和微流体)

  • 程玄 (博士生,研究方向:海空界面气泡声学问题)

  • 陈利伟 (硕士生,研究方向:声涡旋散射和信号处理)

  • 陆啸天 (硕士生,研究方向:水下运动、集群目标声学问题)


***诚挚欢迎有志于开展物理声学水声工程声波操控微粒和微流体等研究方向的学生/博士后加盟***

  • 第十一届船舶力学学术委员会委员(振动与噪声学组,2023-2028)

  • 美国声学学会高级会员(2会士推荐)

  • 中国声学学会会员

  • *Sound & Vibration期刊编委

  • 物理学期刊《Frontiers in Physics》专题编辑: "Ultrasound Micromanipulations and Ocean Acoustics: From Human Cells to Marine Structures

  • Nanotechnology and Precision Engineering》青年编委

  • 期刊审稿人

  • Physics (Phy. Rev. Lett., Phy. Rev. A, Phy. Rev. E, Phy. Rev. Applied, Phy. Rev. Fluids, Proceedings of the Royal Society A, J. Appl. Phys., Appl. Phys. Lett., Physics of Fluids, 中国物理B, 物理学报, Geophysics);

  • Acoustics (JASA稿件20余篇, Ultrasonics, J. Sound Vib., Wave Motion, Shock Vib.);

  • Modeling and Computations (Applied Mathematics and Computation; Applied Mathematical Modelling; Engineering Analysis with Boundary Elements);

  • Engineering (Ocean Enginnering; Communications Engineering; Micromachines; Sensors, Applied Science, Remote Sensing) …

  • * 学位论文函评专家(中国科学院大学、复旦大学、浙江大学)


  • 2024.01 - 2026.12:国家级青年人才项目,主持

  • 2023.11 - 2025.11:科技委基础研究领域重点项目,主持

  • 2022.12 - 2025.12:“双一流”建设项目人才科研经费,100万RMB,主持

  • 2020.12 - 2022.11:法国I-SITE基金会国际人才项目,14.2万欧元,主持

  • Invited talks at international/domestic conferences (The invited speaker is underlined)


  • Edited book

  • [M1] Z. Gong, F. Cai, W. Li, T. Baasch, eds. (2023)., Ultrasound Micromanipulations and Ocean Acoustics: From Human Cells to Marine Structures, Lausanne: Frontiers Media SA. ISBN 978-2-8325-2976-8.


  • Journal papers (PDF files are attached with hyperlinks)

  • 2024
    [TBP] S. Li, W. Cui, T. Baasch, B. Wang, Z. Gong*, Eckart streaming with nonlinear high-order harmonics: an example at gigahertz, arXiv:2403.00350 (2024). [DOI]

  • 2023
    [26] Z. Gong*, F. Cai*, W. Li*, T. Baasch*, Editorial: Ultrasound micromanipulations and ocean acoustics: from human cells to marine structures, Front. Phys., 11:1237899 (2023). [DOI]

  • 2022
    [25] Z. Gong, M. Baudoin*, Single beam acoustical tweezers based on focused beams: A numerical analysis of 2D and 3D trapping capabilities, Phys. Rev. Appl., 18: 044033 (2022). [DOI[PDF]

  • 2021
    [24] Z. Gong, M. Baudoin*, Three-Dimensional Trapping and Dynamic Axial Manipulation with Frequency-Tuned Spiraling Acoustical Tweezers: A Theoretical Study, Phys. Rev. Appl., 16: 024034 (2021). [DOI] [PDF]
    [23] Z. Gong*, M. Baudoin, Equivalence between angular spectrum-based and multipole expansion-based formulas of the acoustic radiation force and torque, J. Acoust. Soc. Am. 149(5): 3469-3482 (2021). [DOI] [PDF] [Collections]
    [22] Q. Wang, A. Riaud*, J. Zhou, Z. Gong, M. Baudoin*, Acoustic radiation force on small spheres due to transient acoustic fields, Phys. Rev. Appl., 15: 044034 (2021). [DOI] [PDF]

  • 2020
    [21] Z. Gong, M. Baudoin*, Three-dimensional trapping and assembly of small particles with synchronized spherical acoustical vortices, Phys. Rev. Appl., 14: 064002 (2020). [DOI] [PDF]
    [20] Z. Gong*, M. Baudoin, Acoustic radiation torque on a particle in a fluid: an angular spectrum based compact expression, J. Acoust. Soc. Am., 148(5): 3131-3140 (2020). [DOI] [PDF]
    [19] M. Baudoin*, J.-L. Thomas, R.A. Sahely, J.C. Gerbedoen, Z. Gong, A. Sivery, O. Bou Matar, N. Smagin, P. Favreau, A. Vlandas*, Spatialy selective manipulation of cells with single beam acoustical tweezers, Nature Commu., 11: 4244 (2020). [DOI] [PDF] [News] [Codes]
    [18] Y. Chai*, Z. Gong, Wei Li, Y. Zhang*, Analysis of transient wave propagation in inhomogeneous media using edge-based gradient smoothing technique and bathe time integration method, Eng. Anal. Bound. Elem., 120: 211–222 (2020). [DOI] [PDF]

  • 2019
    [17] Z. Gong, M. Baudoin*, Particle assembly with synchronized acoustical tweezers, Phys. Rev. Appl., 12: 024045 (2019). [DOI] [PDF]
    [16] Z. Gong, P.L. Marston, W. Li*, T-matrix evaluation of three-dimensional acoustic radiation forces on nonspherical objects in Bessel beams with arbitrary order and location, Phys. Rev. E, 99: 063004 (2019). [DOI] [PDF]
    [15] Z. Gong, P.L. Marston, W. Li*, Reversals of Acoustic Radiation Torque in Bessel Beams Using Theoretical and Numerical Implementations in Three Dimensions, Phys. Rev. Appl., 11: 064022 (2019). [DOI] [PDF]
    [14] W. Li, Q. Gui, Z. Gong*, Resonance scattering of an arbitrary Bessel beam by a spherical object, IEEE UFFC, 66: 1364-1372 (2019). [DOI] [PDF]

  • 2018
    [13] Y. Chai, W. Li*, T. Li, Q. Zhang, Z. Gong, Application of smoothed finite element method to two-dimensional exterior problems of acoustic radiation. Int. J. Comp. Methods, 15: 1850029 (2018). [DOI] [PDF]

  • 2017
    [12] W. Li, Y. Chai, Z. Gong*, P.L. Marston, Analysis of forward scattering of an acoustical zeroth-order Bessel beam from rigid complicated (nonspherical) structures, J. Quant. Spectrosc. Radiat. Transf., 200: 146-162 (2017). [DOI] [PDF]
    [11] Z. Gong, P.L. Marston, W. Li*, Y. Chai, Multipole expansion of acoustical Bessel beams with arbitrary order and location, J. Acoust. Soc. Am., 141: EL574-578 (2017). [DOI] [PDF]
    [10] Z. Gong, W. Li*, Y. Chai, Y. Zhao, F.G. Mitri, T-matrix method for acoustical Bessel beam scattering from a rigid finite cylinder with spheroidal endcaps, Ocean Eng., 129: 507-519 (2017). [DOI] [PDF]
    [09] Y. Chai, Z. Gong, W. Li*, T. Li, Q. Zhang, A smoothed finite element method for exterior Helmholtz equation in two dimensions, Eng. Anal. Bound. Elem., 84: 237–252 (2017). [DOI] [PDF]
    [08] Y. Chai, W. Li*, G. Liu, Z. Gong, T. Li, A superconvergent alpha finite element method (SαFEM) for static and free vibration analysis of shell structures, Comput. Struct., 179: 27-47 (2017). [DOI] [PDF]
    [07] W. Li, Z. Gong, Y. Chai*, C. Cheng, T. Li, Q. Zhang, M. Wang, Hybrid gradient smoothing technique with discrete shear gap method for shell structures, Comput. Math. with Appl., 74: 1826-1855 (2017). [DOI] [PDF]

  • 2016
    [06] Z. Gong, W. Li*, F.G. Mitri, Y. Chai, Y. Zhao, Arbitrary scattering of an acoustical Bessel beam by a rigid spheroid with large aspect-ratio, J. Sound Vib., 383: 233-247 (2016). [DOI] [PDF]
    [05] Z. Gong, Y. Chai, W. Li*, Coupled analysis of structural–acoustic problems using the cell-Based smoothed three-node Mindlin plate element, Int. J. Comp. Methods 13: 1640007 (2016). [DOI] [PDF]
    [04] Y. Chai, W. Li*, Z. Gong, T. Li, Hybrid smoothed finite element method for two-dimensional underwater acoustic scattering problems, Ocean Eng., 116: 129-141 (2016). [DOI] [PDF]
    [03] Y. Chai, W. Li*, T. Li, Z. Gong, X. You, Analysis of underwater acoustic scattering problems using stable node-based smoothed finite element method, Eng. Anal. Bound. Elem., 84: 237–252 (2016). [DOI] [PDF]
    [02] Y. Chai, W. Li*, Z. Gong, T. Li, Hybrid smoothed finite element method for two dimensional acoustic radiation problems, Appl. Acoust., 103: 90–101 (2016). [DOI] [PDF]

  • 2015
    [01] W. Li, J. Li, Z. Gong*, Study on underwater acoustic scattering of a Bessel beam by rigid objects with arbitrary shapes, Acta. Phys. Sin., 64: 154305 (2015). [DOI] [PDF]


  • 本科生:《智能船舶基础 I 》


  • 研究生:《理论声学》


  • 三维声辐射力计算软件包(Nature Communications期刊文章附件)[Codes]

  • 龚志雄,陈利伟,范军,一种基于声涡旋空间相位相关分析的目标探测方法 (申请号:2024105829058)

  • 2023年入选国家级青年人才项目

  • 2023年度上海交通大学“小米青年学者

  • 2022年当选美国声学学会资深会员(Elected ASA Member)

  • 2021年入选上海海外高层次青年领军人才

  • 2020年ASA Early Career Meeting Support Award

版权所有 © 2014 上海交通大学船舶海洋与建筑工程学院 沪交ICP备05053   流量统计