个人简介
陈尧,副研究员,主要从事金属材料力学行为、疲劳损伤与寿命预测、疲劳断裂微观解析等方面研究工作。近3年在领域权威TOP期刊Int. J. Fatigue,JMA,M&D,MSEA,Eng Fract Mech等发表SCI论文10余篇。
【学习及工作经历】
2021.06-至今,四川大学力学科学与工程系,副研究员(专职科研)
2020.09-2021.06,四川大学力学科学与工程系,助理研究员
2016.09-2020.06,四川大学,博士
2012.09-2015.06,西华大学,硕士
2008.09-2012.06,西南科技大学,学士
【承担的主要课程】
理论力学
力学科研训练
【主持或参与的科研项目】
1.国家自然科学基金青年基金项目,镁合金搅拌摩擦焊接头微区演化与超长寿命疲劳行为研究(主持)
2.中央高校基本科研项目,镁合金搅拌摩擦焊接接头长寿命疲劳失效机理与性能提高研究(主持)
3.国家自然科学基金重大仪器研发专项,复杂载荷-环境下超长寿命疲劳振动加速综合实验系统研制(参与)
4.国家自然科学基金重点项目,微结构敏感超高周疲劳机理与超低速裂纹扩展研究(参与)
5.国家自然科学基金面上项目,基于超声振动加载方法的双轴超高周实验系统研制及其应用(参与)
6.国家自然科学基金面上项目,高温高频条件下航空合金焊接接头超长寿命疲劳损伤机理与寿命预测研究(参与)
7.国家自然科学基金青年基金项目,超声冲击细晶表面提升β型钛合金微动疲劳性能的实验研究(参与)
研究领域
1.疲劳失效微结构损伤表征与解析
2.特殊能场下的疲劳损伤修复与仿生延寿
3.先进结构材料的抗疲劳优化设计
近期论文
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[1]Chen Y.(陈尧), Liu F.L., He C., Li L., Wang C., Liu Y.J.*, Wang Q.Y.*. Effect of ultrasonic peening treatment on the fatigue behaviors of a magnesium alloy up to very high cycle regime.Journal of Magnesium and Alloys, 2021 (https://doi.org/10.1016/j.jma.2021.07.028). (SCI中科院一区TOP,IF = 10.088)
[2]Chen Y.(陈尧), Zhang R.F. He C., Liu F.L., Yang K., Wang C., Wang, Q.Y.*, Liu, Y.J.*. Effect of texture and banded structure on the crack initiation mechanism of a friction stir welded magnesium alloy joint in very high cycle fatigue regime.Int. J. Fatigue, 136 (2020) 105617. (SCI中科院一区TOP,IF = 5.186)
[3]Chen Y.(陈尧), He C., Yang K., Zhang H., Wang C., Wang, Q.Y.*, Liu, Y.J.*. Effects of microstructural inhomogeneities and micro-defects on tensile and very high cycle fatigue behaviors of the friction stir welded ZK60 magnesium alloy joint.Int. J. Fatigue, 2019, 122: 218–227. (SCI中科院一区TOP,IF = 5.186)
[4]Chen Y.(陈尧), He C., Liu F.L., Wang C., Xie Q., Wang, Q.Y.*, Liu,Y.J.*. Effect of microstructure inhomogeneity and crack initiation environment on the very high cycle fatigue behavior of a magnesium alloy.Int. J. Fatigue, 131(2020)105376. (SCI中科院一区TOP,IF = 5.186)
[5]Liu, Y.J.,Chen, Y.*(陈尧,通讯作者), He, C., Liu, F.L., Yang, K., Li, L., Zhang H., Wang C., Wang, Q.Y.*. Vacuum retarding and air accelerating effect on the high-cycle and very-high-cycle fatigue behavior of a ZK60 magnesium alloy.Materials & Design, 198 (2021): 109310. (SCI中科院一区TOP,IF = 7.991)
[6]Liu Y.J., Liu F.L., He R.X., Wang Q.Y., Wang C, He C, Kashif K. M.,Chen Y.*(陈尧,通讯作者).Mechanical behaviors of Electron Beam Welded Titanium Alloy up to Very High Cycle Fatigue under Different Process Conditions [J].Materials Science and Engineering: A, 802 (2021): 140685.(SCI中科院一区TOP,IF = 5.234)
[7]Liu F.L.,Chen Y.(陈尧), He C., Wang C., Li L., Liu Y.J.*, Wang Q.Y.*. Very long life fatigue failure mechanism of electron beam welded joint for titanium alloy at elevated temperature.Int. J. Fatigue, 152 (2021):106446. (SCI中科院一区TOP,IF = 5.186)
[8]Liu F.L.,Chen Y.(陈尧), He C., Li L., Wang C., Li H.Z., Zhang H., Wang Q.Y. *, Liu Y.J.*. Tensile and very high cycle fatigue behaviors of a compressor blade titanium alloy at room and high temperatures.Materials Science and Engineering: A, 811 (2021): 141049. (SCI中科院一区TOP,IF = 5.234)
[9]Liu F.L., He C.,Chen Y.(陈尧), Zhang H., Wang Q.Y.*, Liu Y.J.*. Effects of defects on tensile and fatigue behaviors of selective laser melted titanium alloy in very high cycle regime.Int. J. Fatigue, 140 (2020):105795. (SCI中科院一区TOP,IF = 5.186)
[10]Yang K., Huang Q., Zhong B., Wang Q.Y.*,Chen Y.(陈尧), Su N., Liu H.Q. Enhanced extra-long life fatigue resistance of a bimodal titanium alloy by laser shock peening.Int. J. Fatigue, 141 (2020): 105868. (SCI中科院一区TOP,IF = 5.186)
[11]Li H.Z., Chen H., Xu L.Y.*, Wang Q.Y.*,Chen Y.(陈尧), et al.A creep damage model for low cycle fatigue based on the equivalent creep stress: Establishment, verification and application.Engineering Fracture Mechanics, 2021, 107899.(SCI)
[12]Wang Q.Y.,Chen Y.(陈尧), Liu Y.J., et al. The effect of stress ratios on the very high cycle fatigue behavior of 9% Cr turbine steel at 630° C.Materials, 2020, 13(16): 3444. (SCI)
[13]Liu F.L., Zhang H., Liu H.Q.,Chen Y.(陈尧),Kashif K.M., Wang Q.Y.*, Liu Y.J.*. Influence of welded pores on very long-life fatigue failure of the electron beam welding joint of TC17 titanium alloy.Materials, 2019, 12(11): 1825. (SCI)
[14]Hu Y.T.,Chen Y.(陈尧), He C., Liu, Y.J., Wang, Q.Y.*, Wang C.*. Bending Fatigue Behavior of 316L Stainless Steel up to Very High Cycle Fatigue Regime.Materials, 2020, 13(21): 4820. (SCI)
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