姓名:吴建钊
办公室:延长校区(力学所311)
通信地址:上海市广中路788号力学所,邮编:200444
电子邮件:jianzhao_wu@shu.edu.cn
【工作经历】
2023/04 -今,上海大学,力学与工程科学学院,副研究员
2019/10-2023/03,上海大学,力学与工程科学学院,博士后
【教育经历】
2016/03-2019/06 法国里昂中央理工大学/法国流体力学和声学实验室(LMFA) 流体力学 工学博士
2013/09-2016/02 北京航空航天大学 流体机械 工学硕士
2009/09-2013/08 北京航空航天大学 应用物理学 理学学士
【研究方向】
微重力流体力学;振动热湍流;湍流热对流;湍流基本理论、输运和控制
【发表论文】
[1] Meng, W. S., Zhao, C. B., Wu, J. Z., Wang, B. F.*, Zhou, Q.*, & Chong, K. L.* (2024). Simulation of flow and debris migration in extreme ultraviolet. Physics of Fluids, 36, 023322
[2] Guo, X., Wu, J. Z.*, Wang, B., Zhou, Q., & Chong, K. L.* (2023). Flow structure transition in thermal vibrational convection. Journal of Fluid Mechanics, 974, A29.
[3] Huang, Z. L., Guo, X. L., Wu, J. Z.*, Wang, B. F., Chong, K. L., & Zhou, Q.* (2023). Rayleigh-number dependence of the critical vibration frequency in vibrating thermal turbulence. Physical Review Fluids, 8(11), 113501. (Editors’ suggestion)
[4] Zhou, Y. X., Wu, J. Z.*, Shen, J., Dong, S. W., & Lu, Z. M. (2023). On the scale locality and vortex stretching in homogeneous shear turbulence. Physics of Fluids, 35(7), 075126.
[5] Wang, B. F.*, Wu, J. L., Wu, J. Z., Chong, K. L., Liu, Y. L., & Zhou, Q. (2023). Experimental study of heat transfer in a rectangular cell with built-in lattice channels. Physics of Fluids, 35(7), 075128.
[6] Wu, J. Z., Wang, B. F.*, Chong, K. L.*, Dong, Y. H., Sun, C., & Zhou, Q.* (2022). Vibration-induced ‘anti-gravity’ tames thermal turbulence at high Rayleigh numbers. Journal of Fluid Mechanics, 951, A13.
[7] Jin, T. C., Wu, J. Z.*, Zhang, Y. Z., Liu, Y. L., & Zhou, Q.* (2022). Shear-induced modulation on thermal convection over rough plates. Journal of Fluid Mechanics, 936, A28.
[8] Zhao, C. B., Wang, B. F., Wu, J. Z.*, Chong, K. L.*, & Zhou, Q.* (2022). Suppression of flow reversals via manipulating corner rolls in plane Rayleigh–Bénard convection. Journal of Fluid Mechanics, 946, A44.
[9] Li, J., Wang, B.F.*, Qiu, X., Wu, J.Z.*, Zhou, Q., Fu, S., & Liu, Y.L.* (2022). Three-dimensional vortex dynamics and transitional flow induced by a circular cylinder placed near a plane wall with small gap ratios. Journal of Fluid Mechanics, 953, A2.
[10] Guo, X. Q., Wang, B. F.*, Wu, J. Z.*, Chong, K. L., & Zhou, Q.* (2022). Turbulent vertical convection under vertical vibration. Physics of Fluids, 34(5), 055106.
[11] Xia Z.L., Zhao C.B., Wu J.Z.*, Wang B.F., Chong K.L.* (2022) Temperature response to periodic modulation in internal heating convection. Physics of Fluids, 34, 125133
[12] Li, J., Wang, B.F., Qiu, X., Wu, J.Z., Zhou, Q., Fu, S., & Liu, Y.L. (2022). The dynamics of cylinder-wake/boundary-layer interaction revealed by turbulent transports. Physics of Fluids, 34, 115136.
[13] Zhao, C. B., Zhang, Y. Z., Wang, B. F., Wu, J. Z., Chong, K. L., & Zhou, Q. (2022). Modulation of turbulent Rayleigh-Bénard convection under spatially harmonic heating. Physical Review E, 105(5), 055107.
[14] Wu, J. Z., Wang, B. F.*, & Zhou, Q. (2022). Massive heat transfer enhancement of Rayleigh-Bénard turbulence over rough surfaces and under horizontal vibration. Acta Mechanica Sinica, 38(2), 321319.
[15] Wu, J. Z., Dong, D. L., Wang, B. F.*, Dong, Y. H., & Zhou, Q. (2022). Tuning turbulent convection through rough element arrangement. Journal of Hydrodynamics, 1-7.
[16] Wu, J. Z., Wang, B. F.*, Lu, Z. M., & Zhou, Q. (2022). The heat transfer enhancement by unipolar charge injection in a rectangular Rayleigh–Bénard convection. AIP Advances, 12(1), 015212
[17] Shen, J., Peng, C., Wu, J.Z, Chong, K. L., Lu, Z.*, & Wang, L. P. (2022). Turbulence modulation by finite-size particles of different diameters and particle–fluid density ratios in homogeneous isotropic turbulence. Journal of Turbulence, 23(8), 433-453.
[18] Wu, Z. F., Wu, J. Z., Wang, B. F., & Lu, Z. M.* (2022). Effect of Stokes number on energy modulation of the fluid in turbulent particle-laden channel flows. Journal of Hydrodynamics, 34(3), 510-521.
[19] Xia, S. N., Wu, J. Z.*, Wan, Z. H., Wang, B. F.*, Lu, Z. M., & Zhou, Q. (2021). Thermal convection in a tilted rectangular box. AIP Advances, 11(10), 105217.
[20] Cheng, J. J., Wu, J. Z.*, Liu, Y. L., & Lu, Z. M. (2021). Sidewall controlling large-scale flow structure and reversal in turbulent Rayleigh-Bénard convection. Journal of Turbulence, 22(6), 380-392.
[21] Yang, T., Wang, B.F, Wu, J.Z.*, Lu, Z., & Zhou, Q. (2021). Horizontal convection in a rectangular enclosure driven by a linear temperature profile. Applied Mathematics and Mechanics, 42(8), 1183-1190.
[22] Wu, J. Z., Dong, Y. H., Wang, B. F.*, & Zhou, Q.* (2021). Phase decomposition analysis on oscillatory Rayleigh–Bénard turbulence. Physics of Fluids, 33(4), 045108.
[23] Wu, J. Z., Fang, L.*, Shao, L., & Lu, L. P. (2018). Theories and applications of second-order correlation of longitudinal velocity increments at three points in isotropic turbulence. Physics Letters A, 382(25), 1665-1671.
[24] Wu, J. Z., & Fang, L.*(2018). Two-dimensional free-surface flow under gravity: A new benchmark case for SPH method. AIP Advances, 8(2), 025220.
[25] Wang, C. H., Zhang, J., & Wu, J. Z. (2018). Inter-scale transfer of the large-scale background anisotropy under periodic conditions. AIP Advances, 8(12), 125025.
[26] Yao, S., Fang, L., Lv, J., Wu, J., & Lu, L. (2014). Multiscale three-point velocity increment correlation in turbulent flows. Physics Letters A, 378(11-12), 886-891.
[27] Fang, L., Ge, M. W., & Wu, J. Z. (2013). Comment on “A self-adjusting flow dependent formulation for the classical Smagorinsky model coefficient” [Phys. Fluids 25, 055102 (2013)]. Physics of Fluids, 25(9), 099102.
【科研项目】
[1] 国家自然科学基金委员会,青年项目,无重力条件下振动驱动的热湍流能量输运特性研究, 2022 01至2024-12, 30万元,在研,主持
[2] 上海市科学委员会,浦江计划A类,微重力环境下振动驱动热湍流的流动结构和传热特性研究, 2021-10至2023-09, 30万元,结题,主持
[3] 中国博士后科学基金委员会,面上项目,Rayleigh-Bénard 热对流中系统振动抑制湍流传热的物理机制研究,202-11至2021-10,8万元,结题,主持
[4] 国家自然科学基金委员会,湍流结构重大研究计划重点项目,浮力驱动湍流中系统振动对湍流结构生成演化及输运的影响研究,2021.01~2024.12,400万元,在研,参与
[5] 国家自然科学基金委员会,面上项目,均匀剪切湍流中不同尺度结构相互作用及输运机理研究,2021-01至2024-12,66万元,在研,参与
【讲授课程】
[1] 计算流体力学(本科生)
[2] 流动稳定性与湍流理论(研究生)
