2024 1. Di Wu, Yongxiang Hu*, Guohu Luo, Yu Zhou. Tilting behaviors of metal microjet in laser-induced forward transfer. Journal of Manufacturing Science and Engineering-Transactions of the ASME, 2024, 146(3): 031005. 2. Jiancheng Jiang, Zhi Li, Yongxiang Hu*, Siyuan Chen, Yiqiao Song. Density-based topology optimization of multi-condition peening pattern for laser peen forming. International Journal of Mechanical Sciences, 2024, 267: 108968. 3. Guohu Luo, Di Wu, Yu Zhou, Yongxiang Hu*, Siyuan Chen. Alternate deposition and remelting microdroplets via single laser for printing low-defect and high-performance metal micropillars. International Journal of Machine Tools and Manufacture, 2024, 197: 104136. 4. Yongxiang Hu*, Yu Zhou, Guohu Luo, Dege Li, Minni Qu. Femtosecond laser-induced nanoparticle implantation into flexible substrate for sensitive and reusable microfluidics SERS detection. International Journal of Extreme Manufacturing, 2024, 6(4): 45005. 5. Yenan Meng, Yu Zhou, Xiaoxiang Wang, Weiyu Wei, Yongxiang Hu, Bin Chen*. Direct Nanosecond Multiframe Imaging of Irreversible Dynamics in 4D Electron Microscopy. Nano Letters, 2024, 24(24): p. 7219-7226. 6. Yu Zhou¹, Yenan Meng¹, Guohu Luo, Bin Chen, Dongping Zhong*, Yongxiang Hu*. Laser-Induced Stress-Driven Nanoplate Jumping Visualized by Ultrafast Electron Microscopy. ACS Nano, 2024. 7. Jiancheng Jiang, Zhi Li, Yi Zhang, Siyuan Chen, Yongxiang Hu*. Process planning for laser peen forming of complex geometry: An analytical-based inverse study. Thin-Walled Structures, 2024: 112274. 2023 1. Guohu Luo, Di Wu, Yongxiang Hu*, Zhenqiang Yao. A unified analytical model for the flight distance of flying microdroplet before solidification. Advanced Powder Technology, 2023, 34(2): 103934. 2. Ruoyu Yang, Yongxiang Hu*. Determination of process window for laser peening of thin metal sheets by localized indentation analysis. The International Journal of Advanced Manufacturing Technology, 2023, 126: 623–634. 3. Jiancheng Jiang, Yongxiang Hu*, Xueting He. Process-based surface flattening method for laser peen forming of complex geometry. Journal of Manufacturing Processes, 2023, 92: 371-383. 4. Quan Li, Mingyu Gong*, Jiancheng Jiang, YW Chen, HY Ma, YJ Wu, Yongxiang Hu, Atomic-level quantification of twinning shears in magnesium alloy. Acta Materialia, 2023, 246: 118665. 5. Jiancheng Jiang, Yongxiang Hu*, Xinsen Tang. Peening pattern optimization with integer eigen-moment density for laser peen forming of complex shape. Structural and Multidisciplinary Optimization, 2023, 66(4): 84. 6. Yifei Peng¹, Guohu Luo¹, Yongxiang Hu*, Dingbang Xiong*. Dynamic deformation mechanism in submicro-laminated copper with interlamellar graphene multilayers. Acta Materialia, 2023, 252: 118941. 7. Di Wu, Guohu Luo, Yongxiang Hu*, Yu Zhou, Meng Chen. Printing regime for single metal microdroplet deposition in laser-induced forward transfer. Optics and Lasers in Engineering, 2023, 167: 107617. 8. Yifei Peng¹, Guohu Luo¹, Jiayu Chen, Yongxiang Hu*, Dingbang Xiong*. Enhanced Energy Dissipation of Graphene/Cu Nanolaminates under Extreme Strain Rate Ballistic Perforation. Composites Part A: Applied Science and Manufacturing, 2023, 172: 107611. 9. Yu Zhou, Guohu Luo, Yongxiang Hu*, Di Wu, Cheng Hu. Femtosecond laser printing patterned nanoparticles on flexible substrate by tuning plasmon resonances via polarization modulation. International Journal of Machine Tools and Manufacture, 2023, 189: 104040. 10. Han Cheng, Yongxiang Hu*. Crack face closure effect and opening behaviors of fatigue pre-crack treated by laser peening. International Journal of Fatigue, 2023: 107740. 11. Ruoyu Yang, Yongxiang Hu*. Plastic deformation mechanisms and their threshold pressures of Ti6Al4V thin-walled structures induced by laser peen forming. Optics & Laser Technology, 2023, 167: 109722. 2022 1. Guohu Luo, Di Wu, Yu Zhou, Yongxiang Hu*, Zhenqiang Yao, Laser printing of large-scale metal micro/nanoparticle array: Deposition behavior and microstructure. International Journal of Machine Tools and Manufacture, 2022, 173: 103845. 2. Yifei Peng,Guohu Luo, Yongxiang Hu*, Ding-Bang Xiong*, Extreme strain rate deformation of nacre-inspired graphene/copper nanocomposites under laser-induced hypersonic micro-projectile impact. Composites Part B: Engineering, 2022, 235(15): 109763. 3. Yu Zhou, Guohu Luo, Di Wu, Yongxiang Hu*, Efficient modeling of metal ablation irradiated by femtosecond laser via simplified two-temperature model coupling molecular dynamics. Journal of Manufacturing Process, 77, 783-793, 2022. 4. Guohu Luo, Di Wu, Yu Zhou, Yongxiang Hu*, Zhenqiang Yao. Elucidating ejection regimes of metal microdroplets in voxel-based laser-induced forward transfer. Additive Manufacturing, 2022, 55: 102814 5. Maziar Toursangsaraki,YongxiangHu*. Crystal plasticity evaluation of laser peening effects on improving high-cycle fatigue life of Al-Li friction stir welded joints. Materials & Design, 2022, 223: 111147 6. Maziar Toursangsaraki, Yongxiang Hu*, Tianyang Zhang. Crystal plasticity quantification of laser peening strengthening effects on AA2195-T6 friction stir welded joints. International Journal of Advanced Manufacturing Technology, 2022, 120, 11: 7873-7893 7. Yaofei Sun, Zhibao Hou, Zhenqiang Yao*, Yongxiang Hu. Gradient structure and mechanical behavior induced by multiple laser peening in 304 austenitic stainless steel. The International Journal of Advanced Manufacturing Technology, 2022, 120(5-6): 3383-3392. 2021 1. Maziar Toursangsaraki, Quan Li, Yongxiang Hu*, Huamiao Wang, Duo Zhao, Yaobang Zhao. Crystal plasticity modeling for mechanical property prediction of AA2195-T6 friction stir welded joints. Materials Science & Engineering A, 2021, 823:141677. 2. Maziar Toursangsaraki, Huamiao Wang, Yongxiang Hu*, Dhandapanik Karthik, Crystal Plasticity Modeling of Laser Peening Effects on Tensile and High Cycle Fatigue Properties of 2024-T351 Aluminum Alloy[J]. Journal of Manufacturing Science and Engineering, ASME Transactions, 2021, 143(7): 071015. 3. Dhandapanik Karthik, Jiancheng Jiang, Yongxiang Hu*, Zhenqiang Yao, Effect of multiple laser shock peening on microstructure, crystallographic texture and pitting corrosion of Aluminum-Lithium alloy 2060-T8. Surface and Coatings Technology, 2021: 127354. 4. Yu Zhou, Guohu Luo, Yongxiang Hu*, Di Wu, Zhenqiang Yao, Interaction properties between molten metal and quartz by molecular dynamics simulation. Journal of Molecular Liquids, 2021, 342: 117474. 5. Jiancheng Jiang, Yongxiang Hu*, Maziar Toursangsaraki, Improvement of numerical instabilities in process planning of laser peen forming based on perimeter constraint, Advanced Laser Processing and Manufacturing V. SPIE, 2021, 11892: 35-49. 6. Maziar Toursangsaraki, Yongxiang Hu*, Jiancheng Jiang, Experimental investigation of laser peening effects on tensile properties of AA2195-T6 friction stir welded joints, Advanced Laser Processing and Manufacturing V. SPIE, 2021, 11892: 26-34. 2020 1. Mingsheng Luo, Yongxiang Hu*, L. Hu, Z. Yao. Efficient process planning of laser peen forming for complex shaping with distributed eigen-moment. Journal of Materials Processing Technology, 2020, 279: 116588. 2. Yongxiang Hu*, Han Cheng, Jianhua Yu, Zhenqiang Yao, An experimental study on crack closure induced by laser peening in pre-cracked aluminum alloy 2024-T351 and fatigue life extension, International Journal of Fatigue, 2020, 130: 105232. 3. D. Karthik, Y. Hu, Z. Yao. Grain orientation and crystallographic texture governed gradient oxidation in laser peening. Materials Letters, 2020, 268: 127630. 2019 1. Yongxiang Hu*, Yufei Xie, Di Wu, Zhenqiang Yao, Quantitative evaluation of specimen geometry effect on bending deformation of laser peen forming. International Journal of Mechanical Sciences, 2019, 150: 404-410. 2. Ruoyu Yang, Yongxiang Hu*, Mingsheng Luo, Han Cheng, Zhenqiang Yao, Distortion control of thin sections by single-sided laser peening, Optics and Lasers in Engineering, 115 (2019) 90-99. 3. Yongxiang Hu*, Mengqi Lai, Zonghao Hu, Zhenqiang Yao, Effect of multiple laser peening on surface integrity and microstructure of laser additive manufactured Ti6Al4V titanium alloy, Rapid Prototyping Journal, 2019. 4. Jie Zhao, Yongxiang Hu*, Surface morphology formation of Ti films in laser-induced forward transfer, Surface Topography-Metrology and Properties, 2019, 7(2): 025022. 5. Y.X. Hu*, Y. Song, Y. Li, Z.Q. Yao, An analytical model to predict interfacial burr height for metal stack drilling, Proc. Inst. Mech. Eng. Part B-J. Eng. Manuf., 2019: 233(1): 99-108. 2018 1. Yongxiang Hu*, Ruoyu Yang, Dongyu Wang, Zhenqiang Yao. Geometry distortion and residual stress of alternate double-sided laser peening of thin section component. Journal of Materials Processing Technology, 2018, 251: 197-204. 2. M. Luo, Y. Hu*, D. Qian, Z. Yao. Numerical modelling and mechanism analysis of hybrid heating and shock process for laser-assisted laser peen forming. Journal of Manufacturing Science and Engineering, Transaction of ASME, 2018,140(11): 111009. 2017 1. Zhengyu Zhang, Yongxiang Hu*, Zhenqiang Yao. Shape Prediction for Laser Peen Forming of Fiber Metal Laminates by Experimentally Determined Eigenstrain. Journal of Manufacturing Science and Engineering, Transaction of ASME, 2017, 139(4): 041004. 2. Yongxiang Hu*, Han Cheng, Jiaxi Xu and Zhenqiang Yao. A coupling model to simulate the dynamic process of blister-actuated nanosecond laser-induced forward transfer. Journal of Physics D: Applied Physics, 2017, 50(32): 325305. 2016 1. Hu, Y.*, Luo, M., and Yao, Z., Increasing the Capability of Laser Peen Forming to Bend Titanium Alloy Sheets with Laser-Assisted Local Heating, Materials & Design, 2016, 90: 364-372. 2015 1. Y. Hu*, X. Zheng, D. Wang, et al. Application of laser peen forming to bend fibre metal laminates by high dynamic loading. Journal of Materials Processing Technology, 2015, 226: 32-39. 2. Y. Hu*, Z. Li, X. Yu, et al. Effect of elastic prestress on the laser peen forming of aluminum alloy 2024-T351: Experiments and eigenstrain-based modeling. Journal of Materials Processing Technology, 2015, 221(0): 214-224. 2014 1. Hu, Y.X*, Li, Z., Li, K.M, Yao, Z.Q. Predictive Modeling and Uncertainty Quantification of Laser Shock Processing by Bayesian Gaussian Processes With Multiple Outputs. Journal of Manufacturing Science and Engineering, Transaction of ASME, 2014. 136(4), 041014. 2. K. Li, Z. Yao, Y. Hu*, et al. Friction and wear performance of laser peen textured surface under starved lubrication. Tribology International, 2014, 77(0): 97-105. 2013 1. A. Vasu, Y.X Hu, R.V. Grandhi, Differences in plasticity due to curvature in laser peened components, Surface and Coatings Technology, 235 (2013) 648-656. 2. K.M. Li., Y.X. Hu, Z.Q. Yao. Experimental study of micro dimple fabrication based on laser shock processing. Optics & Laser Technology, 2013, 48: 216-225. 2012 & older 1. Y.X. Hu*, R.V. Grandhi. Efficient numerical prediction of residual stress and deformation for large-scale laser shock processing using the eigenstrain methodology. Surface and Coatings Technology, 2012, 206(15): 3374-3385. 2. Yongxiang Hu*, Kangmei Li, Chenjie Qi, Zhenqiang Yao, Ramana V. Grandhi. Size effect on indentation depth of oxygen-free high purity copper induced by laser shock processing. Transactions of Nonferrous Metals Society of China 22(2012) s573−s578. 3. Y.X Hu*, Z. Yao, X. Xu. Experimental Investigation on the Bending Deformation of thin 1060 Pure Aluminum Sheet by Laser Peen Forming. In: Champaigne J, ed, The 11th International Conference on Shot Peening, South Bend, Indiana, USA, 2011: 341-346. 4. Yongxiang Hu*, Xiaoxia Xu, Zhenqiang Yao. Laser peen forming induced two way bending of thin sheet metals and its mechanisms. Journal of Applied Physics, 2010, 108(7): 073117.1-073117.7. 5. Yongxiang Hu, Yefei Han, Zhenqiang Yao, and Jun Hu. Three-Dimensional Numerical Simulation and Experimental Study of Sheet Metal Bending by Laser Peen Forming. Transactions of ASME, Journal of Manufacturing Science and Engineering, 2010, 132(6): 061001.1-061001.10. Patents |
