[1] |
韩恩厚. 核电站关键材料在微纳米尺度上的环境损伤行为研究:进展与趋势[J]. 金属学报, 2011, 47(7): 769-776.HAN Enhou. Research trends on micro and nano-scale materials degradation in nuclear power plant[J]. Acta Metallurgica Sinica, 2011, 47(7): 769-776.
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[2] |
肖厦子, 宋定坤, 楚海建, 等. 金属材料力学性能的辐照硬化效应[J]. 力学进展, 2015, 45(1): 141-178.XIAO Xiazi, SONG Dingkun, CHU Haijian, et al. Irradiation hardening for metallic materials[J].Advances in Mechanics, 2015, 45(1): 141-178.
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[3] |
DUNDURS J, MURA T. Interaction between an edge dislocation and a circular inclusion[J]. Journal of the Mechanics and Physics of Solids, 1964, 12(3): 177-189.
|
[4] |
KEER L M. Interaction between an edge dislocation and a rigid elliptical inclusion[J]. Journal of Applied Mechanics, 1986, 53(2): 383.
|
[5] |
SROLOVITZ D J, PETKOVIC-LUTON R A, LUTON M J. Edge dislocation-circular inclusion interactions at elevated temperatures[J]. Acta Metallurgica, 1983, 31(12): 2151-2159.
|
[6] |
MURA T. Micromechanics of Defects in Solids[M]. New York: Springer Science & Business Media, 2013.
|
[7] |
FANG Q H, LIU Y W. Size-dependent interaction between an edge dislocation and a nanoscale inhomogeneity with interface effects[J]. Acta Materialia, 2006, 54(16): 4213-4220.
|
[8] |
WANG X, PAN E. Interaction between an edge dislocation and a circular inclusion with interface slip and diffusion[J]. Acta Materialia, 2011, 59(2): 797-804.
|
[9] |
DUDAREV S L, SUTTON A P. Elastic interactions between nano-scale defects in irradiated materials[J]. Acta Materialia, 2017, 125: 425-430.
|
[10] |
PROVILLE L, BAKO B. Dislocation depinning from ordered nanophases in a model fcc crystal: From cutting mechanism to Orowan looping[J]. Acta Materialia, 2010, 58(17): 5565-5571.
|
[11] |
XU S, XIONG L, CHEN Y, et al. Edge dislocations bowing out from a row of collinear obstacles in Al[J]. Scripta Materialia, 2016, 123: 135-139.
|
[12] |
GROH S. Transformation of shear loop into prismatic loops during bypass of an array of impenetrable particles by edge dislocations[J]. Materials Science and Engineering: A, 2014, 618: 29-36.
|
[13] |
DUTTA A, BHATTACHARYA M, GAYATHRI N, et al. The mechanism of climb in dislocation-nanovoid interaction[J]. Acta Materialia, 2012, 60(9): 3789-3798.
|
[14] |
ASARI K, HETLAND O S, FUJITA S, et al. The effect of stacking fault energy on interactions between an edge dislocation and a spherical void by molecular dynamics simulations[J]. Journal of Nuclear Materials, 2013, 442(1-3): 360-364.
|
[15] |
OKITA T, ASARI K, FUJITA S, et al. Effect of the stacking fault energy on interactions between an edge dislocation and a spherical void in fcc metals at various spatial geometries[J]. Fusion Science and Technology, 2014, 66(1): 289-294.
|
[16] |
DOIHARA K, OKITA T, ITAKURA M, et al. Atomic simulations to evaluate effects of stacking fault energy on interactions between edge dislocation and spherical void in face-centred cubic metals[J]. Philosophical Magazine, 2018, 98(22): 2061-2076.
|
[17] |
ZHU B, HUANG M, LI Z. Atomic level simulations of interaction between edge dislocations and irradiation induced ellipsoidal voids in alpha-iron[J]. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 2017, 397: 51-61.
|
[18] |
DOS REIS M L, PROVILLE L, SAUZAY M. Modeling the climb-assisted glide of edge dislocations through a random distribution of nano-sized vacancy clusters[J]. Physical Review Materials, 2018, 2(9): 093604.
|
[19] |
DRS J, PROVILLE L, MARINICA M C. Dislocation depinning from nano-sized irradiation defects in a bcc iron model[J]. Acta Materialia, 2015, 99: 99-105.
|
[20] |
HUANG Minsheng, ZHU Yaxin, LI Zhenhuan. Dislocation dissociation strongly influences on Frank-Read source nucleation and microplasticy of materials with low stacking fault energy[J]. Chinese Physics Letters, 2014, 31(4): 046102.
|
[21] |
KEYHANI A, ROUMINA R. Dislocation-precipitate interaction map[J]. Computational Materials Science, 2018, 141: 153-161.
|
[22] |
WANG Y U, JIN Y M, CUITINO A M, et al. Nanoscale phase field microelasticity theory of dislocations: Model and 3D simulations[J]. Acta Materialia, 2001, 49(10): 1847-1857.
|
[23] |
WANG Y, LI J. Phase field modeling of defects and deformation[J]. Acta Materialia, 2010, 58(4): 1212-1235.
|
[24] |
HUNTER A, BEYERLEIN I J, GERMANN T C, et al. Influence of the stacking fault energy surface on partial dislocations in fcc metals with a three-dimensional phase field dislocations dynamics model[J]. Physical Review B, 2011, 84(14): 144108.
|
[25] |
HUNTER A, ZHANG R F, BEYERLEIN I J, et al. Dependence of equilibrium stacking fault width in fcc metals on the γ-surface[J]. Modelling and Simulation in Materials Science and Engineering, 2013, 21(2): 025015.
|
[26] |
SHEN C, WANG Y. Phase field model of dislocation networks[J]. Acta Materialia, 2003, 51(9): 2595-2610.
|
[27] |
SHEN C, WANG Y. Incorporation of γ-surface to phase field model of dislocations: Simulating dislocation dissociation in fcc crystals[J]. Acta Materialia, 2004, 52(3): 683-691.
|
[28] |
ZHENG S, ZHENG D, NI Y, et al. Improved phase field model of dislocation intersections[J]. npj Computational Materials, 2018, 4(1): 20.
|
[29] |
ZHENG S L, NI Y, HE L H. Alternative transmission mode and long stacking fault formation during a dissociated screw dislocation across a coherent sliding interface[J]. Journal of Physics D: Applied Physics, 2015, 48(39): 395301.
|
[30] |
ZHENG S, NI Y, HE L. Phase field modeling of a glide dislocation transmission across a coherent sliding interface[J]. Modelling and Simulation in Materials Science and Engineering, 2015, 23(3): 035002.
|
[31] |
LIU H, GAO Y, QI L, et al. Phase-field simulation of Orowan strengthening by coherent precipitate plates in an aluminum alloy[J]. Metallurgical and Materials Transactions A, 2015, 46(7): 3287-3301.
|
[32] |
WANG Y U, JIN Y M, KHACHATURYAN A G. Phase field microelasticity theory and modeling of elastically and structurally inhomogeneous solid[J]. Journal of Applied Physics, 2002, 92(3): 1351-1360.
|
[33] |
CHEN L Q, SHEN J. Applications of semi-implicit Fourier-spectral method to phase field equations[J]. Computer Physics Communications, 1998, 108(2-3): 147-158.
|
[1] |
韩恩厚. 核电站关键材料在微纳米尺度上的环境损伤行为研究:进展与趋势[J]. 金属学报, 2011, 47(7): 769-776.HAN Enhou. Research trends on micro and nano-scale materials degradation in nuclear power plant[J]. Acta Metallurgica Sinica, 2011, 47(7): 769-776.
|
[2] |
肖厦子, 宋定坤, 楚海建, 等. 金属材料力学性能的辐照硬化效应[J]. 力学进展, 2015, 45(1): 141-178.XIAO Xiazi, SONG Dingkun, CHU Haijian, et al. Irradiation hardening for metallic materials[J].Advances in Mechanics, 2015, 45(1): 141-178.
|
[3] |
DUNDURS J, MURA T. Interaction between an edge dislocation and a circular inclusion[J]. Journal of the Mechanics and Physics of Solids, 1964, 12(3): 177-189.
|
[4] |
KEER L M. Interaction between an edge dislocation and a rigid elliptical inclusion[J]. Journal of Applied Mechanics, 1986, 53(2): 383.
|
[5] |
SROLOVITZ D J, PETKOVIC-LUTON R A, LUTON M J. Edge dislocation-circular inclusion interactions at elevated temperatures[J]. Acta Metallurgica, 1983, 31(12): 2151-2159.
|
[6] |
MURA T. Micromechanics of Defects in Solids[M]. New York: Springer Science & Business Media, 2013.
|
[7] |
FANG Q H, LIU Y W. Size-dependent interaction between an edge dislocation and a nanoscale inhomogeneity with interface effects[J]. Acta Materialia, 2006, 54(16): 4213-4220.
|
[8] |
WANG X, PAN E. Interaction between an edge dislocation and a circular inclusion with interface slip and diffusion[J]. Acta Materialia, 2011, 59(2): 797-804.
|
[9] |
DUDAREV S L, SUTTON A P. Elastic interactions between nano-scale defects in irradiated materials[J]. Acta Materialia, 2017, 125: 425-430.
|
[10] |
PROVILLE L, BAKO B. Dislocation depinning from ordered nanophases in a model fcc crystal: From cutting mechanism to Orowan looping[J]. Acta Materialia, 2010, 58(17): 5565-5571.
|
[11] |
XU S, XIONG L, CHEN Y, et al. Edge dislocations bowing out from a row of collinear obstacles in Al[J]. Scripta Materialia, 2016, 123: 135-139.
|
[12] |
GROH S. Transformation of shear loop into prismatic loops during bypass of an array of impenetrable particles by edge dislocations[J]. Materials Science and Engineering: A, 2014, 618: 29-36.
|
[13] |
DUTTA A, BHATTACHARYA M, GAYATHRI N, et al. The mechanism of climb in dislocation-nanovoid interaction[J]. Acta Materialia, 2012, 60(9): 3789-3798.
|
[14] |
ASARI K, HETLAND O S, FUJITA S, et al. The effect of stacking fault energy on interactions between an edge dislocation and a spherical void by molecular dynamics simulations[J]. Journal of Nuclear Materials, 2013, 442(1-3): 360-364.
|
[15] |
OKITA T, ASARI K, FUJITA S, et al. Effect of the stacking fault energy on interactions between an edge dislocation and a spherical void in fcc metals at various spatial geometries[J]. Fusion Science and Technology, 2014, 66(1): 289-294.
|
[16] |
DOIHARA K, OKITA T, ITAKURA M, et al. Atomic simulations to evaluate effects of stacking fault energy on interactions between edge dislocation and spherical void in face-centred cubic metals[J]. Philosophical Magazine, 2018, 98(22): 2061-2076.
|
[17] |
ZHU B, HUANG M, LI Z. Atomic level simulations of interaction between edge dislocations and irradiation induced ellipsoidal voids in alpha-iron[J]. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 2017, 397: 51-61.
|
[18] |
DOS REIS M L, PROVILLE L, SAUZAY M. Modeling the climb-assisted glide of edge dislocations through a random distribution of nano-sized vacancy clusters[J]. Physical Review Materials, 2018, 2(9): 093604.
|
[19] |
DRS J, PROVILLE L, MARINICA M C. Dislocation depinning from nano-sized irradiation defects in a bcc iron model[J]. Acta Materialia, 2015, 99: 99-105.
|
[20] |
HUANG Minsheng, ZHU Yaxin, LI Zhenhuan. Dislocation dissociation strongly influences on Frank-Read source nucleation and microplasticy of materials with low stacking fault energy[J]. Chinese Physics Letters, 2014, 31(4): 046102.
|
[21] |
KEYHANI A, ROUMINA R. Dislocation-precipitate interaction map[J]. Computational Materials Science, 2018, 141: 153-161.
|
[22] |
WANG Y U, JIN Y M, CUITINO A M, et al. Nanoscale phase field microelasticity theory of dislocations: Model and 3D simulations[J]. Acta Materialia, 2001, 49(10): 1847-1857.
|
[23] |
WANG Y, LI J. Phase field modeling of defects and deformation[J]. Acta Materialia, 2010, 58(4): 1212-1235.
|
[24] |
HUNTER A, BEYERLEIN I J, GERMANN T C, et al. Influence of the stacking fault energy surface on partial dislocations in fcc metals with a three-dimensional phase field dislocations dynamics model[J]. Physical Review B, 2011, 84(14): 144108.
|
[25] |
HUNTER A, ZHANG R F, BEYERLEIN I J, et al. Dependence of equilibrium stacking fault width in fcc metals on the γ-surface[J]. Modelling and Simulation in Materials Science and Engineering, 2013, 21(2): 025015.
|
[26] |
SHEN C, WANG Y. Phase field model of dislocation networks[J]. Acta Materialia, 2003, 51(9): 2595-2610.
|
[27] |
SHEN C, WANG Y. Incorporation of γ-surface to phase field model of dislocations: Simulating dislocation dissociation in fcc crystals[J]. Acta Materialia, 2004, 52(3): 683-691.
|
[28] |
ZHENG S, ZHENG D, NI Y, et al. Improved phase field model of dislocation intersections[J]. npj Computational Materials, 2018, 4(1): 20.
|
[29] |
ZHENG S L, NI Y, HE L H. Alternative transmission mode and long stacking fault formation during a dissociated screw dislocation across a coherent sliding interface[J]. Journal of Physics D: Applied Physics, 2015, 48(39): 395301.
|
[30] |
ZHENG S, NI Y, HE L. Phase field modeling of a glide dislocation transmission across a coherent sliding interface[J]. Modelling and Simulation in Materials Science and Engineering, 2015, 23(3): 035002.
|
[31] |
LIU H, GAO Y, QI L, et al. Phase-field simulation of Orowan strengthening by coherent precipitate plates in an aluminum alloy[J]. Metallurgical and Materials Transactions A, 2015, 46(7): 3287-3301.
|
[32] |
WANG Y U, JIN Y M, KHACHATURYAN A G. Phase field microelasticity theory and modeling of elastically and structurally inhomogeneous solid[J]. Journal of Applied Physics, 2002, 92(3): 1351-1360.
|
[33] |
CHEN L Q, SHEN J. Applications of semi-implicit Fourier-spectral method to phase field equations[J]. Computer Physics Communications, 1998, 108(2-3): 147-158.
|