[1] 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.
[2] Wu W., Liu Q., Wang B., Curved surface effect on high-speed droplet impingement[J]. Journal of Fluid Mechanics, 2021, 909, A7.
[3] 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.
[4] 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.
[5] Gao Z., Wu W., Wang B., The Effects of Nanoscale Nuclei on Cavitation[J]. Journal of Fluid Mechanics, 2021, 911, A20.
[6] Gao Z., Wu W., Sun W., et al. Understanding the Stabilization of a Bulk Nanobubble: A Molecular Dynamics Analysis[J]. Langmuir, 2021, 37(38): 11281-11291.(封面文章)
[7] 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.
[8] Wu W, Wang B., Liu Q, Characteristics of the microjets during shock-induced tandem bubble collapse[C]. 11th ICMF 2023, Kobe, Japan.
[9] Wu Wangxia, Liu Qingquan and Wang Bing. Pressure amplification induced by multiple cavities collapse along high-speed droplet impact inside a tube[C]. ICTAM 2020+1, 2021 Milan, Italy.
[10] 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.
[11] Wu Wangxia, Wang Bing, Impaction of a High-speed Droplet Embedded with Decentered Air Cavity[C]. 18th USNCTAM 2018, Chicago, USA.
[12] 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.
[13] Yang C, Liu Y, Wu W, et al. 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.
[14] Jing L, Yang C, Wu W, et al. 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.
[15] 吴汪霞,王兵,王晓亮,等.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.
[16] 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.
[17] 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.(邀请报告)
[18] 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.
[19] 吴汪霞, 杨策, 荆磊, 等. 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.
[20] 杨策, 吴汪霞, 荆磊, 等. 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.
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.