教育经历：

1997年9月---2001年7月      复旦大学物理系，获学士学位

2001年9月---2003年5月      美国纽约大学物理系，获硕士学位

2003年5月---2006年5月      美国纽约大学物理系，获理学博士学位

工作经历：

2006年12月---2009年7月    美国加州大学(UCSB)物理系 任职：博士后

2009年7月---2011年6月      美国耶鲁大学地球物理系   任职：博士后

2011年7月---2011年7月      美国耶鲁大学地球物理系 任职：研究员

2012年2月至今                    bet356亚洲版在线体育    任职：教授, 博导

2013年-2021年   Electomagnetism（电磁学）  物理专业本科生课程，全英文授课

2020年                普通物理A                             非物理专业本科生课程

2019年-2021年   物理类基础科学前沿讲座       本科生课程

获奖：

2016年               bet356亚洲版在线体育“传承感恩”科创青年奖教金；

2016年               bet356体育登录入口优秀共产党员荣誉称号；

2014年               bet356体育登录入口“师风师德优秀教师”。

荣誉：

国家高层次人才(科技领军人才) 2021；

国家海外高层次青年人才 (2012)；

科技部中青年科技创新推进计划 (2020);

上海市浦江人才计划 (2012-2015);

国家自然科学基金重大研究计划培育项目 (2022-2025);

国家自然科学基金面上项目 (2018-2022);

国家自然科学基金面上项目 (2016-2020);

国家自然科学基金(NSFC)与香港研究资助局(RGC)合作项目 (2016-2020);

国家自然科学基金青年项目 (2012-2015);

上海市自然科学基金面上项目 (2022-2025)。

担任国家“国家及青年人才”面试评委；国家自然科学基金委重点、面上和青年项目通讯评委；教育部“青年长江学者”通讯评委
《力学季刊》编委；上海市力学学会第十三届理事会副主任
Physical Review Letters, Journal of Fluid Mechanics, Physical Review Fluids, Physical Review E, J. Heat Mass Trans 等国际期刊常邀审稿人
美国物理学会，地理学会和Sigma Xi会员

代表性论文:

(1)“Inverse centrifugal effect induced by collective motion of vortices in rotating turbulent convection.” S.-S. Ding, K. Chong, J.-Q. Shi, G.-Y. Ding, H.-Y. Lu, K.-Q. Xia*, J.-Q. Zhong*. Nature Communications, 12, 5585 (2021);

(2)“Flow structures and heat transport in Taylor-Couette system with axial temperature gradient” X.-Y. Leng, D. Krasnov, B.-W. Li, J.-Q. Zhong*. J. Fluid Mech., 920, A42 (2021);
(3)“Heat transport scaling and transition in geostrophic rotating convection with varying aspect ratio” H.-Y. Lu, G.-Y. Ding, J.-Q. Shi, K.-Q. Xia*, J.-Q. Zhong*. Phys. Rev. Fluids (Letters), 6, L071501 (2021).
(4)“Robust propagation of internal coastal Kelvin waves in complex domains.” C. Ren, X. Fan, Y. Xia, T. Chen, L. Yang, J.-Q. Zhong*, H. P. Zhang*. Phys. Rev. Fluids (Letters), 6, L022801 (2021);
(5)“Enhanced heat transport in thermal convection with suspensions of expandable particles.” S. Hu, L. Jia, K. Wang, J.-Q. Zhong, J. Zhang*. J. Fluid Mech., 928, R1 (2021);
(6)“Vortices as Brownian Particles in Turbulent Flows.” K. Chong, J.-Q. Shi, G.-Y. Ding, S.-S.Ding, H.-Y. Lu, J.-Q. Zhong*, K.-Q. Xia*. Science Advances, 6, eaaz1110, 1-7 (2020);
(7)“Fine vortex structure and flow transition to the geostrophic regime in rotating Rayleigh-Bénard convection” J.-Q. Shi, H.-Y. Lu, S.-S. Ding and J.-Q. Zhong*, Phys. Rev. Fluids (Rapid Communications), 5, 011501 (2020);
(8)“Streaming controlled by meniscus shape” Y.-C. Huang*, C. P. Wolfe; J. Zhang, J.-Q. Zhong*, J. Fluid Mech., 895, A1-1, (2020);
(9)“Solidification of binary aqueous solutions under periodic cooling. Part 1. Dynamics of mushy- layer growth,” G.-Y. Ding, A. J. Wells and J.-Q. Zhong*, J. Fluid Mech., 870, 121–146, (2019);
(10)“Solidification of binary aqueous solutions under periodic cooling. Part 2. Distribution of solid fraction,” G.-Y. Ding, A. J. Wells and J.-Q. Zhong*, J. Fluid Mech., 870, 147–174, (2019);
(11)“Temperature fluctuations relevant to thermal-plume dynamics in turbulent rotating Rayleigh-Bénard convection” S.-S. Ding, H.-M. Li, W.-D. Yan and J.-Q. Zhong*, Phys. Rev. Fluids. 4, 023501 (2019);
(12)“The dynamics of an insulating plate over a thermally convecting fluid and its implication for continent movement over convective mantle,” Y. Mao, J.-Q. Zhong and J. Zhang, J. Fluid Mech., 868, 286–315 (2019);
(13)“Stochastic dynamics of fluid–structure interaction in turbulent thermal convection.” J. Huang, J.-Q. Zhong, J. Zhang, and L. Mertz, J. Fluid Mech. (Rapids), 854, R5, (2018);
(14)“Confined Rayleigh-Bénard, Rotating Rayleigh-Bénard and Double Diffusive Convection: A Unifying View on Turbulent Transport Enhancement Through Coherent Structure Manipulation” K.-L. Chong, Y. Yang, S.-D. Huang, J.-Q. Zhong, R. Stevens, R. Verzicco, D. Lohse and K.-Q. Xia, Phys. Rev. Lett. 119, 064501 (2017);
(15)“Enhanced azimuthal rotation of the large-scale flow through stochastic cessations in turbulent rotating convection with large Rossby numbers,” J.-Q. Zhong*, H.-M. Li, X.-Y. Wang, Phys. Rev. Fluids. 2, 044602 (2017);
(16)“Dynamical and statistical phenomena of circulation and heat transfer in periodically forced rotating turbulent Rayleigh-Bénard convection,” S. Sterl, H.-M. Li, J.-Q. Zhong*, Phys. Rev. Fluids. 1, 084401 (2016);
(17) “Dynamics of the Large-Scale Circulation in Turbulent Rayleigh-Bénard Convection with modulated rotation.” J.-Q. Zhong*, S. Sterl, and H.-M. Li, J. Fluid Mech.(Rapids), 778, R4, 1-12 (2015);
(18)“Experimental investigation of time-dependent compositional flux in solidifying binary aqueous solutions.” Z.-C. Yin, Q. Zhou*, and J.-Q. Zhong*, Chinese Journal of Hydrodynamics. 30, 357-364 (2015);
(19) "Steady turbulent density currents on a slope in rotating fluid." G. E. Manucharyan, J.-Q. Zhong and J. S. Wettlaufer, J. Fluid Mech.,746, 405-436 (2014);
(20)"Finite-sample-size effects on convection in mushy layers." J.-Q. Zhong, A. T. Fragoso, A. J. Wells and J. S. Wettlaufer, J. Fluid Mech., 704, 89-108 (2012);
(21) "Mushy layer dynamics in micro and hyper gravity." J. O'Rourke, A. Riggs, C. Guertler, P. Miller, C. Padhi, M. Popelka, J.-Q. Zhong and J. S. Wettlaufer, Phys. Fluids 24, 103305 (2012);
(22)“Streaks to Rings to Vortex Grids: Generic Patterns in Transient Convective Spin-Up of an evaporation fluid.” J.-Q. Zhong, M. Patternson and J. S. Wettlaufer, Phys. Rev. Lett., 105, 044504 (2010);
(23)“Heat transport and the large-scale circulation in rotating turbulent Rayleigh-Bénard convection.” J.-Q. Zhong and G. Ahlers. J. Fluid Mech., 665, 300-333 (2010);
(24)“Finite-size effects lead to supercritical bifurcations in turbulent rotating Rayleigh-Bénard convection.” S. Weiss, R. Stevens, J.-Q. Zhong, H. Clercx, D. Lohse, and G. Ahlers, Phys. Rev. Lett., 105, 225401 (2010);
(25)“Prandtl-, Rayleigh-, and Rossby-number dependence of heat transport in turbulent rotating Rayleigh-Bénard convection.” J.-Q. Zhong, R.J.A.M. Stevens, H. J. H. Clercx, R. Verzicco, D. Lohse, and G. Ahlers, Phys. Rev. Lett.(cover letter), 102, 044502 (2009);
(26)“Enhanced heat-transport by turbulent two-phase Rayleigh-Bénard convection.” J.-Q. Zhong, D. Funfschilling and G. Ahlers*. Phys. Rev. Lett., 102, 124501 (2009);
(27)“Transitions between turbulent states in rotating Rayleigh-Bénard convection.” R.J.A.M. Stevens, J.-Q. Zhong, H.J.H. Clercx, G. Ahlers, and D. Lohse*, Phys. Rev. Lett., 103, 024503 (2009);
(28)“Turbulent two-phase Rayleigh-Bénard convection.” J.-Q. Zhong and G. Ahlers, Proceedings of the European Turbulence Conference. ETC12, (2009);
(29)“Prandtl-, Rayleigh-, and Rossby-number dependence of heat transport in turbulent rotating Rayleigh-Bénard convection.” R.J.A.M. Stevens, J.-Q. Zhong, H.J.H. Clercx, D. Lohse, and G. Ahlers, Proceedings of the European Turbulence Conference, ETC12, 529-532 (2009);
(30)(also in:) Advances in Turbulence XII, B. Eckhardt (ed.), Springer Proceedings in Physics 132, Springer-Verlag Berlin Heidelberg (2009);
(31)“Modeling the dynamics of a free boundary on turbulent thermal convection.” J.-Q. Zhong and J. Zhang, Phys. Rev. E, 76, 016307 (2007);
(32)“Dynamical states of a mobile heat blanket on a thermally convecting fluid.” J.-Q. Zhong and J. Zhang*, Phys. Rev. E (Rapid Communications), 75, 055301(R) (2007);
(33)“Thermal convection with a freely moving top boundary.” J.-Q. Zhong and J. Zhang*, Phys. Fluids, 17,115105 (2005).