Work experience

*since 2022.12, Shanghai Jiao Tong University, Associate Professor

*2018.12-2022.12, CNRS UMR8520 IEMN (France), Postdoc (Collaborators: Michael Baudoin, Jean-Louis Thomas)

*12/2016-04/2018, Washington State University (U.S.A.), Visiting scholar (Collaborators: Philip L. Marston)

Education

*09/2013-09/2018, Huazhong University of Science and Technology,Ph.D.

*09/2009-09/2013, Huazhong University of Science and Technology, Bachelor

*Physical Acoustics

*Ocean Acoustics

*Acoustical tweezers

• Editorial Board Member forSound & Vibration

• Guest Associate Editor forFrontiers in Physics

• Early career editor forNanotechnology and Precision Engineering

• Member ofthe Acoustical Society of Americasince 2022 (Associate Member since 2017)

• Member ofthe Acoustical Society of Chinasince 2022 (Student Member since 2017)

• Member ofIEEE UFFC, 2019, 2021

• More than 70 communications in peer-reviewed journals including

• Physics(Phy. Rev. Lett., Phy. Rev. E, Phy. Rev. Applied, Phy. Rev. Fluids,Phy. Rev. A,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, 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) …

• NSCFExcellent Young Scientists Fund Programwhich supports me to work as a principal investigator (PI) on the acoustic manipulation of microparticles and bubble clouds.

• I-SITE Talent project(142K€; Rank 1/5) which supports me to work as an invited postdoctoral fellow with Prof. Michaël BAUDOIN and conduct experiments on acoustical tweezers.

• During my Ph.D., I get involved with several projects including the topics of acoustics and engineering mechanics as a Student leader (+5) or participant (+2) with a total funding of 373K€.

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

• [B20]龚志雄, 陈利伟，范军，基于空间相位信息的涡旋声呐主动探测原理和应用研究,2024全国空间智能遥感与海洋测绘导航学术大会暨先进装备展览会—海洋信息技术论坛，December 21-22, 2024, Weihai (China).

• [B19]龚志雄, 陈利伟，范军，基于空间相位特征的水下目标声探测技术, 西北工业大学海上无人平台技术学科论坛，November 24, 2024, Ningbo (China).

• [B17]龚志雄, 单波束声镊操控微粒和微流体理论与技术, 同济大学物理科学与工程学院格物论坛，November 20, Shanghai (China).

• [B17]龚志雄, 单波束声镊理论和技术：选择性操控及潜在细胞力学测量研究, , October 18-20, 2024, Shanghai (China).[会议日程]

• [B16]龚志雄, 高精度选择性操控细胞的单波束声镊理论与技术,2024年中国声学学会, September 19-22, 2024, Nanjing (China).

• [B15]龚志雄, 单波束声镊操控微粒和微流体理论与技术, , September 18, 2024, Nanjing (China).[海报]

• [B14]Z. Gong, Acoustic vortex beams: From theory to applications, the 7th International Conference on Innovation & Cooperation in Naval Architecture & Marine Engineering (ICNAME2024), August 22-25, 2024, Harbin (China).

• [B13]Z. Gong, Acoustic manipulation of microparticles and microfluidics: Single beam incidence, Lund University, August 12, 2024, Lund (Sweden, Europe).

• [B12]Z龚志雄, 声涡旋高精度选择性操控细胞，中国福利会国际和平妇幼保健院, July 8, 2024, Shanghai (China).

• [B11]Z. Gong, Selective Trapping and Assembly at Cell-sized Level with Single-beam Acoustical Tweezers,PhotonIcs & Electromagnetics Research Symposium, April 21 - 25, 2024, Chengdu (China).

• [B10]龚志雄,声涡旋探测和操控水中目标/微粒,华中科技大学船海学院“黄群讲坛”第十八期, April 2, 2024, Wuhan (China).

• [B9]Z. Gong, 2D and 3D trapping of particles and cells with single beam acoustic tweezers based on focused beams,Multidisciplinary Innovation Forum on Nanotechnology and Precision Engineering, October 22 - 23, 2023, Shenzhen (China).

• [B8]龚志雄, 高次谐波影响下Eckart声流理论,操控与传感学术研讨会, 中科院深圳先进技术研究院，October 23, 2023, Shenzhen (China).

• [B7]龚志雄, 声涡旋散射、操控水中微粒和微流体,水声技术重点实验室2023年海洋信息论坛，第十三期, 哈尔滨工程大学，September 22, 2023, Harbin (China).

• [B6]M. Baudion, R.A. Sahely, O. B. Matar, J.-C. Gerbedoen,Z. Gong, A. Sivery, N. Smagin, J.-L. Thomas, A. Vlandas, Single beam selective acoustical tweezers: from acoustical vortices to focused beams,The 75th Annual Meeting of the American Physical Society’s Division of Fluid Dynamics (APS DFD), 20-22 November 2022, Indiana (United States).

• [B5]Z. Gong, M. Baudion, Single focused-beam acoustical tweezers,The 182nd Meeting of the Acoustical Society of America, 23-27 May 2022, Denver (United States).

• [B4]M. Baudion, R.A. Sahely,Z. Gong, O.B. Matar, J.-C. Gerbedoen, N. Smagin, R. Chutani, Active holographic tweezers based on spiraling interdigitated transducers,The 182nd Meeting of the Acoustical Society of America, 23-27 May 2022, Denver (United States).

• [B3]Z. Gong, M. Baudion, Small particles assembly using cylindrical Bessel vortices in two dimension,2019 International Congress on Ultrasonics, 3-6 September 2019, Bruges (Belgium).

• [B2]Z. Gong, W. Li, P.L. Marston, Potential of theoretical approach and T-matrix method for designing numerical acoustical tweezers toolbox,The 175th Meeting of the Acoustical Society of America, 7-11 May 2018, Minneapolis (United States).

• [B1]Z. Gong, W. Li, Y. Chai, Y. Zhao, Forward scattering of an acoustical Bessel beam by rigid structures using T-matrix method,The 7th International Conference on Computational Methods, 1-4 August 2016, Berkeley (United States).

  
  

  
  

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  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.
  

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  Journal papers(PDF files are attached with hyperlinks)

• 2025
  [29]S. Li,Z. Gong*,Reversing the acoustic contrast factor by tuning the medium can make focused beams trap cells in three dimensions, Phys. Fluids,37, 012003(2025).[DOI][PDF]

• 2024
  [28]D. Shen, et. al, Ionic Hydrogel-Based Moisture Electric Generators for Underwater Electronics, Adv. Sci., 2024, 2408954 (2024). [DOI][PDF].
  [27]S. Li, W. Cui, T. Baasch, B. Wang,Z. Gong*, Eckart streaming with nonlinear high-order harmonics: an example at gigahertz, Phys. Rev. Fluids, 9: 084201 (2024). [DOI][PDF]

• 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][PDF]

• 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]

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  Conference papers(PDF files are attached with hyperlinks)

• 2024
  [04]X. Cheng, S. Li,Z. Gong*, J. Fan, Linear Modulation of the Resonant Frequency of a Double-bubble Model Below an Air-Water Interface, 2024 OES China Ocean Acoustics (COA) (2024).[DOI][PDF]
  [03]X. Lu,Z. Gong*, Analytical Solution of Radiated Acoustic Field by Moving Monopolar and Dipolar Sources, 2024 OES China Ocean Acoustics (COA) (2024).[DOI][PDF]

• 2016
  [02]S. Liu,Z. Gong*, Y. Chai, W. Li, Underwater acoustic scattering of Bessel beam by spherical shell using T-matrix method, 2016 IEEE/OES China Ocean Acoustics (COA) (2016).[DOI][PDF]

• 2015
  [01]Z. Gong, W. Li, Y. Chai, Acoustic resonance scattering of Bessel beam by elastic spheroids in water, Proceedings of ICCM2015, pp.1-9, (2015).[DOI][PDF]

• Undergraduate course: Intelligent Marine Vehicles Basics I (Signals and Systems)

• Graduate course: Theoretical acoustics

* Computational software package of three-dimensional acoustical radiation forces, see the attached codes in our NC paper[Codes]

* A correlation method of spatial phase information based on acoustic vortex, China Patent (Appl. No. 2024105829058)

* Device and method for focused beams with tunable focal length, China Patent (No.ZL 2024 1 0582905.8)

* 2024 Gold Award inChina International College Students’ Innovation Competition 2024(Shanghai Division)

*2023 Young Scholar ofXiaomi Foundation

*2020ASA Early Career Meeting Support Award(By one of the main societiesin acoustics)

*2017 China Scholarship Council (CSC) (to support me as a visiting scholar moving outside of China)

*2016HUST Postgraduate Overseas Short-term Study Program Scholarship