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| Dynamics of interfacial gravity-capillary waves in three-dimensional fluids of great depth 期刊论文 COMPUTERS & FLUIDS, 2021, 卷号: 231, 页码: 13 Authors: Li HY(李海艳); Wang Z(王展) Adobe PDF(1679Kb)  |  Favorite  |  View/Download:285/49  |  Submit date:2021/11/15 Isotropic model ETD Interfacial wave Capillary-gravity wave |
| Effect of plasticity and adhesion on the stick-slip transition at nanoscale friction 期刊论文 TRIBOLOGY INTERNATIONAL, 2021, 卷号: 164, 页码: 8 Authors: Hu JQ(胡剑桥); Liu XM(刘小明); Wei YG(魏悦广) Adobe PDF(5926Kb)  |  Favorite  |  View/Download:308/83  |  Submit date:2021/11/01 Stick-slip transition Adhesion and plasticity Critical shear stress Thermal effect Molecular dynamics simulation |
| Mortar dynamic coupled model for calculating interface gas exchange between organic and inorganic matters of shale 期刊论文 ENERGY, 2021, 卷号: 236, 页码: 16 Authors: Cao GH(曹高辉); Jiang WB(江文滨); Lin M(林缅); Ji LL(姬莉莉); Xu ZP(徐志朋); Zheng SP(郑思平); Hao, Fang Adobe PDF(3192Kb)  |  Favorite  |  View/Download:299/61  |  Submit date:2021/11/01 Shale gas Dynamic transport Interface exchange Mortar |
| Interaction between the edge dislocation dipole pair and interfacial misfit dislocation network in Ni-based single crystal superalloys 期刊论文 INTERNATIONAL JOURNAL OF SOLIDS AND STRUCTURES, 2021, 卷号: 228, 页码: 8 Authors: Zhang ZW(张志伟); Fu, Qiang; Wang J(王军); Yang R(杨荣); Xiao P(肖攀); Ke FJ(柯孚久); Lu CS(卢春生) Adobe PDF(3166Kb)  |  Favorite  |  View/Download:363/57  |  Submit date:2021/09/08 Ni-based single crystal superalloys Edge dislocation dipole pair Interfacial misfit dislocation network Interacting mechanism Molecular dynamics |
| Rapid multiscale pore network modeling for drainage in tight sandstone 期刊论文 JOURNAL OF PETROLEUM SCIENCE AND ENGINEERING, 2021, 卷号: 204, 页码: 15 Authors: Xu ZP(徐志朋); Lin M(林缅); Jiang WB(江文滨); Ji LL(姬莉莉); Cao GH(曹高辉) Adobe PDF(15776Kb)  |  Favorite  |  View/Download:296/54  |  Submit date:2021/08/03 Multiscale pore network modeling Rapid Two-phase flow Tight sandstone |
| Microscopic deformation mechanism and main influencing factors of carbon nanotube coated graphene foams under uniaxial compression 期刊论文 NANOTECHNOLOGY, 2021, 卷号: 32, 期号: 34, 页码: 11 Authors: Wang, Shuai; Wang C(王超); Khan, Muhammad Bilal; Chen, Shaohua Adobe PDF(2157Kb)  |  Favorite  |  View/Download:311/49  |  Submit date:2021/08/03 carbon nanotube-coated graphene foam uniaxial compression numerical experiment mechanical property microscopic deformation mechanism |
| Simultaneous Improvement of Yield Strength and Ductility at Cryogenic Temperature by Gradient Structure in 304 Stainless Steel 期刊论文 NANOMATERIALS, 2021, 卷号: 11, 期号: 7, 页码: 12 Authors: Tan S(覃双); Yang MX(杨沐鑫); Yuan FP(袁福平); Wu XL(武晓雷) Adobe PDF(57205Kb)  |  Favorite  |  View/Download:307/33  |  Submit date:2021/08/16 gradient structure ductility strain hardening martensitic transformation hetero-de-formation-induced hardening |
| Gradient design of bio-inspired nacre-like composites for improved impact resistance 期刊论文 COMPOSITES PART B-ENGINEERING, 2021, 卷号: 215, 页码: 11 Authors: Wei ZQ(魏志全); Xu XH(许向红) Adobe PDF(11396Kb)  |  Favorite  |  View/Download:416/104  |  Submit date:2021/06/07 Nacre-like structure Gradient design Impact resistance |
| Atomistic modeling for the extremely low and high temperature-dependent yield strength in a Ni-based single crystal superalloy 期刊论文 MATERIALS TODAY COMMUNICATIONS, 2021, 卷号: 27, 页码: 6 Authors: Zhang, Zhiwei; Fu, Qiang; Wang J(王军); Yang R(杨荣); Xiao P(肖攀); Ke FJ(柯孚久); Lu CS(卢春生) Adobe PDF(4012Kb)  |  Favorite  |  View/Download:298/67  |  Submit date:2021/08/30 Ni-based single crystal superalloy Yield strength Temperature-dependence Dislocation activities Molecular dynamics |
| Directional Metastable Wetting Evolution of Droplets on Artificial Patterned Microcavity Surfaces 期刊论文 ADVANCED MATERIALS INTERFACES, 2021, 页码: 9 Authors: Xu WS(徐文帅); Liu Y(刘宇); Xiao BY(肖伯雅); Jiang H(姜恒); Chen M(陈猛); Wang YR(王育人) Adobe PDF(1710Kb)  |  Favorite  |  View/Download:384/98  |  Submit date:2021/06/15 directional wetting transition metastable interfaces microcavity surfaces power law |