1. HZhang, Q wang, X Gong, T Wang, W Zhang, K Chen,C Wang, Y Liu*, Q Wang*. Dependence on temperature of compression behavior and deformation mechanisms of Nickel-based single crystal CMSX-4, Journal of Alloys and Compounds,866:158878, 2021 2. Y Liu, Y Chen*, C He, F Liu, K Yang, L Li, H Zhang,C Wang, Q Wang*. Vacuum retarding and air accelerating effect on the high-cycle and very-high-cycle fatigue behavior of a ZK60 magnesium alloy, Materials & Design,198:109310,2021 3. YHu, Y Chen, C He, Y Liu, Q Wang*,C Wang*. Bending Fatigue Behavior of 316L Stainless Steel up to Very High Cycle Fatigue Regime, Materials, 13(21):4820,2020 4. Q Wang, Q Wang, X Gong, T Wang, W Zhang, L Li, Y Liu, C He,C Wang, H Zhang*. A comparative study of low cycle fatigue behavior and microstructure of Cr-based steel at room and high temperatures, Materials & Design, 195:109000, 2020 5. Y Chen, R Zhang, C He, F Liu, K Yang,C Wang, Q Xie, Q Wang*, Y Liu*. 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. International Journal of Fatigue,131:105617, 2020 6.X Li, R Zhang, X Wang, Y Liu,C Wang, H Zhang, L Li, C He*, Q Wang*. Effect of high temperature on crack initiation of super austenitic stainless steel 654SMO in very high cycle fatigue, Materials & Design,193(2):108750,2020 7. Y Chen, C He, F Liu,C Wang, Q Xie, Q Wang*, Y Liu*. Effect of microstructure inhomogeneity and crack initiation environment on the very high cycle fatigue behavior of a magnesium alloy, International Journal of Fatigue,131:105376, 2020 8.C Wang, Y Liu, A Nikitin, Q Wang*, M Zhou. A general scenario of fish‐eye crack initiation on the life of high‐strength steels in the very high‐cycle fatigue regime, Fatigue & Fracture of Engineering Materials & Structures, 42 (9), 2183-2194,2019 9.Y Chen, C He, K Yang, H Zhang,C Wang, Q Wang*, Y Liu*. Effects of microstructural inhomogeneities and micro-defects on tensile and very high cycle fatigue behaviors of the friction stir welded ZK60 magnesium alloy joint, International Journal of Fatigue,122, 218-227, 2019 10.C Wang, J Petit, Z Huang, D Wagner*. Investigation of crack initiation mechanisms responsible for the fish eye formation in the Very High Cycle Fatigue regime, International Journal of Fatigue,119, 320-329,2019 11.曹小建,王宠, 王清远*. 超声表面冲击对Ti6Al4V的生物相容性的影响。工程科学与技术,50:196-202,2018 12.岳怀俊; 蒋文涛*; 王宠; 万志鹏; 樊瑜波.针对3D打印材料孔洞应力集中计算的映射算法。医用生物力学, (02): 108-113 , 2018 13.万志鹏, 蒋文涛,王宠*, 王清远, 李亚兰. 三维打印Ti-6Al-4V合金孔洞几何特征与空间分布研究。 生物医学工程学杂志, 34(5), 876-882, 2017 14.Cao X, Xu X,Wang C, Pyoun Y, Wang Q*. Effect of UNSM on the corrosion fatigue behavior of Ti-6Al-4V in SBF. Metals, 7(10), 440, 2017 15.曹小建, 片英植, 金江, 许罗鹏,王宠, 王清远*. 超声表面冲击强化对TC4钛合金拉压疲劳性能的影响. 中国表面工程, 30(2), 48-55, 2017 16.万志鹏,王宠, 蒋文涛*, 黄志勇, 王清远. 孔洞缺陷对3D打印Ti-6Al-4V合金疲劳试样应力分布的影响. 实验力学, 32(1),1-8, 2017 17.Wagner D*.,Wang C., Huang Z., Bathias C., Surface crack initiation mechanism for body centered cubic materials in the gigacycle fatigue domain, International Journal of Fatigue, 93, 292-300, 2016 18.Favier V.*, Blanche A*.,Wang C.*, Phung N.*, Ranc N.*, Wagner D.*, Bathias C., Chrysochoos A.*, Mughrabi H.*, Very high cycle fatigue for single phase ductile materials: Comparison between α-iron, copper and α-brass polycrystals, International Journal of Fatigue, 93, 326-338, 2016 19.Z.Y.Huang,C.Wang*, Q.Y. Wang, Thermal Dissipation Calculation in Very High Cycle Fatigue", Key Engineering Materials, Vol. 664, pp. 55-61, 2016 20.X.J. Cao, L. P. Xu,C. Wang, J. Jin, Q. Y. Wang*. Effect of Shot Peening on the Long Life Fatigue Properties of Ti6Al4V with Different Heat Treatment, Key Engineering Materials, Vol. 664, pp. 81-86, 2016 21.Wang, C.; Wagner, D.; Wang, Q.; Huang, Z.*; Bathias, C. VHCF Crack Initiation Mechanism According to 3D Micron Abreast Pipes Model, Fatigue Fract Eng M, 2015,38,1324-1333 22.Huang, Z.Y.; Liu, H.Q.;Wang, C.*; Wang, Q. Y. Fatigue life dispersion and thermal dissipation investigations for titanium alloy TC17 in very high cycle regime, Fatigue Fract Eng M, 38, 1285-1293, 2015 23.Chai, G.*; Forsman, T.; Gustavsson, F.;Wang, C. Formation of fine grained area in martensitic steel during very high cycle fatigue, Fatigue Fract Eng M, 38, 1315-1323,2015 24.C. Wang, A. Blanche, D. Wagner*, A. Chrysochoos, C. Bathias, Dissipative and microstructural effects associated with fatigue crack initiation on an Armco iron, International Journal of Fatigue, Volume 58, Pages 152-157, 2014 25.P. Filgueirasb, C. Bathiasa*, E. Palmab, C. Wang, Inducing very high cycle fretting-fatigue in the ultrasonic regime, Tribology International, Volume 76, Pages 57-62, 2014 26.C. Wang, D. Wagner*, C. Bathias, Investigations on the fatigue crack propagation threshold in Very High Cycle Fatigue, Advanced Materials Research Volumes. 891-892, Pages 357-362, 2014 27.C.Bathias*,C.Wang, Initiation From Low cycle fatigue to Gigacycle Fatigue, Advanced Materials Research Volumes. 891-892, Pages 1419-1423, 2014 28.C. Wang, D. Wagner, Q.Y. Wang, C. Bathias*, Gigacycle fatigue initiation mechanism in Armco iron, International Journal of Fatigue, Volume 45, Pages 91-97, 2012 29.王宠, 王清远*. 稀土处理铝合金超声疲劳研究, 四川大学学报 (工程科学版), 40S: 155-158, 2008, 30.王宠, 李棠, 王清远* 2A12铝合金的超长寿命疲劳性能, 材料研究学报,21(S), 213-216, 2007 31.T.Li, Q.Y.Wang*, Q.F.Dou,C.Wang, M.R.Sriraman. Investigations on Fatigue Properties of Die Cast Magnesium Alloy Az91Hp at Very High Cycles. Key Engineering Materials. 353-358:235-238, 2007 |