[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) |