期刊论文(SCI):
[1] Qiao T, Xiong H, Wu W, et al. Investigation on the cavitation characteristics induced by high-intensity focused ultrasonic waves in a near-wall region[J]. Journal of Fluid Mechanics, 2026, 1028: A48.
[2] Qiao T, Xiong H, Wu W. Investigation of cavitation cloud characteristics near a bubble in a high-intensity focused ultrasound field[J]. Physics of Fluids, 2026, 38(2).
[3] Zhang M, Li L, Wu W. Component Matching and Its Role in the Formation of Two-Regime Surge in Centrifugal Compressors[J]. Aerospace Science and Technology, 2026: 112493.
[4] Guo Y, Luo H, Xiong H, Li Y, Deng J, Wu W, et al. Experimental study on cavitation characteristics near the wall in the presence of an attached preset air bubble[J]. Physics of Fluids, 2025, 37(1):013305.
[5] Zhang M, Xu J, Wu W. Flow mechanisms of two-regime flow instability caused by centrifugal compressor volute[J]. Aerospace Science and Technology, 2025, 164: 110389.
[6] Luo H, Y Guo Y, S Xu S, Wen H, Wu W, et al. Characteristics of a laser-induced bubble near the wedge between the gas-liquid interface and solid wall[J]. Physics of Fluids, 2025, 37(1):013308.
[7] Zhang M, Wu W, Zhou C. Numerical Investigation of Flow Evolution in Centrifugal Compressors During Surge[J]. Journal of Turbomachinery, 2024: 1-37.
[8] Xu S, Fan W, Wu W, Wen H., Wang B. Analysis of wave converging phenomena inside the shocked two-dimensional cylindrical water column[J]. Journal of Fluid Mechanics, 2023, 964: A12.
[9] Zhang M, Wu W, Zhou C. Numerical model of predicting surge boundaries in high-speed centrifugal compressors[J]. Aerospace Science and Technology, 2023, 141: 108518.
[10] Zhang E, Wang Z, Wu W, Wang X, Liu Q. Secondary flow and streamwise vortices in three-dimensional staggered wavy-wall turbulence[J]. Flow, 2023, 3: E19.
[11] Geng K., Ce Yang C., Zhao B., Zhao W., Gao J., Hu C., Zhang H., Wu W. Residual circulation budget analysis in a Wells turbine with leading-edge micro-cylinders[J]. Renewable Energy, 2023, 216: 119049.
[12] Wu W., Wang B., Liu Q. Tandem cavity collapse in a high-speed droplet impinging on a 180° constrained wall[J]. Journal of Fluid Mechanics, 2022, 932, A52.
[13] Zhang E, Wu W, Liu Q, et al. Effects of vortex formation and interaction on turbulent mass transfer over a two-dimensional wavy wall[J]. Physical Review Fluids, 2022, 7(11): 114607.
[14] Wu W., Liu Q., Wang B. Curved surface effect on high-speed droplet impingement[J]. Journal of Fluid Mechanics, 2021, 909, A7.
[15] Gao Z., Wu W., Sun W., Wang B. Understanding the Stabilization of a Bulk Nanobubble: A Molecular Dynamics Analysis[J]. Langmuir, 2021, 37(38): 11281-11291.(封面文章)
[16] Gao Z., Wu W., Wang B. The Effects of Nanoscale Nuclei on Cavitation[J]. Journal of Fluid Mechanics, 2021, 911, A20.
[17] Wu W., Wang B., Xiang G. Impingement of high-speed cylindrical droplets embedded with an air/vapour cavity on a rigid wall: numerical analysis[J]. Journal of Fluid Mechanics, 2019, 864: 1058-1087.
[18] Wu W., Xiang G., Wang B. On high-speed impingement of cylindrical droplets upon solid wall considering cavitation effects[J]. Journal of Fluid Mechanics, 2018, 857: 851-877.
期刊论文(EI):
[1] 罗浩天, 郭运吉, 杜文强, 吴汪霞. 预置气泡对近壁空化的防护特性与智能预测[J]. 力学学报, 2026.
[2] 陈晨, 陈家辉, 丰翔, 张未航, 米麒麟, 罗浩天, 吴汪霞. 小球冲击覆膜液体入水过程的动力学行为研究[J]. 力学学报, 2025, 57(9): 1-12.
[3] Luo H, Wu W. Investigation of spherical bubble dynamics under biological environment based on Rayleigh-Plesset equation[C]//17th Asian Congress of Fluid Mechanics (ACFM 2023). IET, 2023, 2023: 149-155.
[4] Zhang M, Wu W. Role of the Inducer in Flow Instability of a High-Speed Centrifugal Compressor Impeller[C]//Turbo Expo: Power for Land, Sea, and Air. American Society of Mechanical Engineers, 2023, 87110: V13DT35A016.
[5] Hou X, Wu X, Wu W, Duan Y., Yuan S. Investigation of cavitation inside the valve plate suction groove of an axial piston pump[C]//17th Asian Congress of Fluid Mechanics (ACFM 2023). IET, 2023, 2023: 83-87.
[6] 吴汪霞, 王兵, 王晓亮, 刘青泉. 非等强度多道冲击波作用下空泡溃灭机制分析[J]. 航空学报, 2021, 42(12):625894.
[7] 吴汪霞, 项高明, 王兵. 高速撞壁液滴空化演化过程的数值模拟[J]. 工程热物理学报, 2018, 39(11): 2444-2447.
[8] 杨策, 吴汪霞, 荆磊, 王本江, 陈山. 非均衡进气双面离心压气机流场差异分析[J]. 工程热物理学报, 2017, 38(11): 2324-2333.
[9] Yang C, Liu Y, Wu W, Jing L, Wang B, Chen S. Circumferential Flow Differences in the Double-Sided Centrifugal Compressor With Non-Balanced Inlets[C]//ASME Turbo Expo 2016: Turbomachinery Technical Conference and Exposition. American Society of Mechanical Engineers, 2016: V008T23A001-V008T23A001.
[10] Jing L, Yang C, Wu W, Chen S. Investigation of an Asymmetric Double Entry Centrifugal Compressor with Different Radial Impellers Matching for a Wide Operating Range[C]//ASME Turbo Expo 2015: Turbine Technical Conference and Exposition. American Society of Mechanical Engineers,2015: V02CT42A023-V02CT42A023.
[11] 吴汪霞, 杨策, 荆磊, 老大中, 陈山. 非对称进气双面压气机叶轮工作模式研究[J]. 工程热物理学报, 2015 (8): 1658-1661.
会议论文:
[1] 曲虹宇, 李彦铭, 吴汪霞. 高速喷注条件下不同燃料液滴的破碎机制研究[C].第三届空天前沿大会, 2026, 4月9-13日, 南京. (优秀宣讲报告)
[2] 李彦铭, 吴汪霞, 滕宏辉. 不同启动方式下液滴破碎机理研究[C].第二届流体界面不稳定性与多介质湍流专题研讨会, 2025, 9月12-14日, 合肥. (优秀墙报奖) [3] Li Y, Wu W, Teng H. Numerical Simulation of the Aerobreakup of Two Droplet Positioned in Tandem under High Speed Flow[C]. The 35th International Symposium on Shock Waves, July 5-14, 2025, Brisbane, Australia.
[4] 李彦铭, 吴汪霞, 滕宏辉*.面向高超喷注环境的双液滴破碎机理研究[C]. CFD基础科学问题研讨会暨国家数值风洞2025交流会, 2025, 10月17-19日, 杭州. [5] Qu H, Li Y, Qian T, Wu W*. Numerical Simulation of Aerobreakup Behavior of Droplet in Different Media in High-speed Flow[C]. CoMEA2025, June 20-22, 2025, Haerbin, China.
[6] 李彦铭, 吴汪霞,滕宏辉. 高超背景下两相界面问题的低耗散近似黎曼问题联合求解方法[C]. 中国力学大会-2025, 2025, 7月18-21日, 长沙.
[7] 陈晨, 吴汪霞. 剪切流影响下微米级气泡生长和分离机制研究[C].中国力学大会-2025, 2025, 7月18-21日, 长沙.
[8] 熊杭凡, 吴汪霞.考虑表面张力的热脉冲诱导薄液膜破碎的高精度数值模拟[C].中国力学大会-2025, 2025, 7月18-21日, 长沙.
[9] 罗浩天, 熊杭凡, 乔天杨, 吴汪霞.超声作用下液滴中心空泡的振荡行为研究[C].中国力学大会-2025, 2025, 7月18-21日, 长沙. [10] 吴汪霞. 高速液滴撞击内在机制研究[C]. 第三届能源领域青年学者沙龙, 2024, 8 月1 - 3 日, 北京.
[11] 吴汪霞, 熊杭凡. 液滴高速撞击过程内在机理与瞬变特性研究[C]. 第八届中国空天动力联合大会, 2024, 7月25-28日, 成都, 四川. (分会场邀请报告) [12] Qian T, Wu W. Numerical investigation of cloud cavitation dynamics in the presence of pre-set bubble in a high-intensity focused ultrasound field[C]. ICTAM2024, August 25-30, 2024, Daegu, Korea. [13] Luo H, Wu W, Xiang G. Experimental studies of the laser induced cavitation bubble dynamics near the wedge region between the free surface and solid wall[C]. ICTAM2024, August 25-30, 2024, Daegu, Korea.
[14] Guo Y, Luo H, Wu W, Teng H. Experimental study of cavitation dynamics near the pre-set air bubble adhered to a rigid boundary[C]. ICTAM2024, August 25-30, 2024, Daegu, Korea. [15] Xiong H, Wu W. Numerical study of high-speed droplet impact on stationary liquid film considering cavitation effect[C]. ICTAM2024, August 25-30, 2024, Daegu, Korea. [16] Qian T, Wu W. Numerical investigation of cloud cavitation dynamics in the presence of pre-set bubble in a high-intensity focused ultrasound field[C]. 10th AJWTFS, November 9-12, 2024, Zhangjiajie, China. [17] 乔天杨, 吴汪霞. 汇聚型超声波诱导下固壁附近空化特性研究[C]. 第二届能源领域青年学者沙龙, 2024, 7 月 26 - 28 日, 华北电力大学, 北京. [18] 李彦铭, 何国胜, 熊杭凡, 吴汪霞.不同来流马赫数下液滴/液柱气动破碎特性的数值研究[C].首届空天前沿大会, 2026, 4月12-15日, 西安. (优秀宣讲报告)
[19] Wu W, Wang B., Liu Q. Characteristics of the microjets during shock-induced tandem bubble collapse[C]. 11th ICMF 2023, Kobe, Japan.
[20] Luo H, Wu W. Investigation of spherical bubble dynamics under focused ultrasonic wave based on Keller-Miksis equation[C]. 15th ICCEU, 2023, Beijing, China.
[21] 吴汪霞,刘青泉,王兵,王晓亮. 液体中多道激波作用下空泡溃灭机制及其诱发的空化行为分析[C], 中国力学大会-2021+1, 2022, 中国, 成都.(分会场邀请报告)
[22] Wu W., Liu Q., Wang B. Pressure amplification induced by multiple cavities collapse along high-speed droplet impact inside a tube[C]. ICTAM 2020+1, 2021, Milan, Italy.
[23] 吴汪霞, 刘青泉, 王兵. 液柱高速撞击引起内在空泡列演化及空泡间作用机制研究[C], 第十一届全国流体力学学术会议, 2020, 中国, 深圳.
[24] Wu W, Wang B., Gao Z. Numerical study of cavitation evolution procedure of perfluorocarbon droplets triggered by expansion waves generated in high-speed impingement[C]. 10th ICMF 2019, Rio de Janeiro, Brazil.
[25] Wu Wangxia, Wang Bing. Impaction of a High-speed Droplet Embedded with Decentered Air Cavity[C]. 18th USNCTAM 2018, Chicago, USA.
[26] Wu Wangxia, Wang Bing, Zhang Wenbin. A Six-equation Two-phase Model in WENO Scheme for Phase Transformation Fronts[C]. 9th ICMF 2016, Firenze, Italy.
出版学术专著
[1] 吴汪霞. 高速撞壁液滴内在瞬变特征及其规律的数值研究[M]. 清华大学出版社, 2022.
