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Philosophical Magazine Volume 86, 2006 - Issue 36
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Original Articles

Cooperative grain boundary sliding in nanocrystalline materials

A. V. Sergueeva University of California, Department of Chemical Engineering & Materials Science, One Shields Avenue, Davis, CA 95616, USA
,
N. A. Mara University of California, Department of Chemical Engineering & Materials Science, One Shields Avenue, Davis, CA 95616, USA
,
N. A. Krasilnikov Ulyanovsk State University, 42 Tolstoy Str., Ulyanovsk 432700, Russia
,
R. Z. Valiev Ufa State Aviation Technical University, Institute of Physics of Advanced Materials, 12 Marks str., Ufa 450000, Russia
&
A. K. Mukherjee University of California, Department of Chemical Engineering & Materials Science, One Shields Avenue, Davis, CA 95616, USACorrespondence[email protected]
Pages 5797-5804 | Received 03 Aug 2005, Accepted 21 Mar 2006, Published online: 24 Nov 2006

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Read on this site (2)

Yingxin Zhao, Qihong Fang & Youwen Liu. (2014) Effect of cooperative nanograin boundary sliding and migration on dislocation emission from a blunt nanocrack tip in nanocrystalline materials. Philosophical Magazine 94:7, pages 700-730.
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M.Yu. Gutkin, I.A. Ovid’ko & N.V. Skiba. (2008) Crack-stimulated generation of deformation twins in nanocrystalline metals and ceramics. Philosophical Magazine 88:8, pages 1137-1151.
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Articles from other publishers (37)

Rebecca A Gallivan, Zachary H Aitken, Antoine Chamoun-Farah, Yong-Wei Zhang & Julia R Greer. (2023) Microstructure-driven mechanical and electromechanical phenomena in additively manufactured nanocrystalline zinc oxide. Nanotechnology 35:6, pages 065706.
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Hong Wang, Dongtao Zhang, Yuqing Li, Jianjun Yang, Wenna Song, Weiqiang Liu & Ming Yue. (2023) Deformation and texture formation mechanism of hot-deformed SmCo5 nanocrystalline magnets. Journal of Alloys and Compounds 934, pages 168071.
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C. Keller, M. Calvat, B. Flipon & F. Barbe. (2022) Experimental and numerical investigations of plastic strain mechanisms of AISI 316L alloys with bimodal grain size distribution. International Journal of Plasticity 153, pages 103246.
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Xiaotao Li & Wentao Ma. (2021) Molecular dynamics simulation and theoretical modeling of free surface effect on nanocrack initiation induced by grain boundary sliding in nanocrystalline materials. Materials Letters 304, pages 130647.
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Y.H. Zhao, J.F. Bingert, T.D. Topping, P.L. Sun, X.Z. Liao, Y.T. Zhu & E.J. Lavernia. (2020) Mechanical behavior, deformation mechanism and microstructure evolutions of ultrafine-grained Al during recovery via annealing. Materials Science and Engineering: A 772, pages 138706.
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I.A. Ovid'ko, R.Z. Valiev & Y.T. Zhu. (2018) Review on superior strength and enhanced ductility of metallic nanomaterials. Progress in Materials Science 94, pages 462-540.
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I.A. Ovid'ko & A.G. Sheinerman. (2017) Grain boundary sliding, triple junction disclinations and strain hardening in ultrafine-grained and nanocrystalline metals. International Journal of Plasticity 96, pages 227-241.
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A. T. AlMotasem, J. Bergström, A. Gåård, P. Krakhmalev & L. J. Holleboom. (2017) Atomistic Insights on the Wear/Friction Behavior of Nanocrystalline Ferrite During Nanoscratching as Revealed by Molecular Dynamics. Tribology Letters 65:3.
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Tengwu He, Wanshen Xiao, Yan Zhang & Haiping Zhu. (2017) Effect of cooperative grain boundary sliding and migration on dislocation emission from a branched crack tip in deformed nanocrystalline solids. International Journal of Fracture 206:1, pages 1-10.
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I.A. Ovid'ko & A.G. Sheinerman. (2016) Free surface effects on stress-driven grain boundary sliding and migration processes in nanocrystalline materials. Acta Materialia 121, pages 117-125.
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Jie Jian, Joon Hwan Lee, Yue Liu, Fauzia Khatkhatay, Kaiyuan Yu, Qing Su, Xinghang Zhang, Liang Jiao & Haiyan Wang. (2016) Plastic deformation in nanocrystalline TiN at ultra-low stress: An in situ nanoindentation study. Materials Science and Engineering: A 650, pages 445-453.
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Leon MishnaevskyJr.Jr. & Evgeny Levashov. (2015) Micromechanical modelling of nanocrystalline and ultrafine grained metals: A short overview. Computational Materials Science 96, pages 365-373.
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T.C. Lowe & R.Z. Valiev. 2014. Advanced Biomaterials and Biodevices. Advanced Biomaterials and Biodevices 1 52 .
Min Yu, Qihong Fang, Hui Feng & Youwen Liu. (2014) Effect of cooperative grain boundary sliding and migration on dislocation emitting from a semi-elliptical blunt crack tip in nanocrystalline solids. Acta Mechanica 225:7, pages 2005-2019.
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Maneesh Mishra, Chaiyapat Tangpatjaroen & Izabela Szlufarska. (2014) Plasticity-Controlled Friction and Wear in Nanocrystalline SiC. Journal of the American Ceramic Society 97:4, pages 1194-1201.
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Jianjun Li & A.K. Soh. (2013) Synergy of grain boundary sliding and shear-coupled migration process in nanocrystalline materials. Acta Materialia 61:14, pages 5449-5457.
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H. Feng, Q.H. Fang, L.C. Zhang & Y.W. Liu. (2013) Effect of cooperative grain boundary sliding and migration on emission of dislocations from a crack tip in nanocrystalline materials. Mechanics of Materials 61, pages 39-48.
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Y.T. Zhu, X.Z. Liao & X.L. Wu. (2012) Deformation twinning in nanocrystalline materials. Progress in Materials Science 57:1, pages 1-62.
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S. V. Bobylev, N. F. Morozov & I. A. Ovid’ko. (2011) Cooperative grain boundary sliding and nanograin nucleation process in nanocrystalline, ultrafine-grained, and polycrystalline solids. Physical Review B 84:9.
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I.A. Ovid’ko, A.G. Sheinerman & E.C. Aifantis. (2011) Effect of cooperative grain boundary sliding and migration on crack growth in nanocrystalline solids. Acta Materialia 59:12, pages 5023-5031.
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A. Sergueeva & A. Mukherjee. 2011. Nanostructured Metals and Alloys. Nanostructured Metals and Alloys 542 593 .
M.Y. Gutkin. 2011. Nanostructured Metals and Alloys. Nanostructured Metals and Alloys 329 374 .
I.A. Ovid’ko, A.G. Sheinerman & N.V. Skiba. (2011) Elongated nanoscale voids at deformed special grain boundary structures in nanocrystalline materials. Acta Materialia 59:2, pages 678-685.
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S.H. Whang. 2011. Nanostructured Metals and Alloys. Nanostructured Metals and Alloys xxi xxxv .
I.A. Ovid’ko & A.G. Sheinerman. (2010) Ductile vs. brittle behavior of pre-cracked nanocrystalline and ultrafine-grained materials. Acta Materialia 58:16, pages 5286-5294.
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Joon Hwan Lee, Ickchan Kim, Dustin M. Hulbert, Dongtao Jiang, Amiya K. Mukherjee, Xinghang Zhang & Haiyan Wang. (2010) Grain and grain boundary activities observed in alumina–zirconia–magnesia spinel nanocomposites by in situ nanoindentation using transmission electron microscopy. Acta Materialia 58:14, pages 4891-4899.
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S. V. Bobylev, N. F. Morozov & I. A. Ovid’ko. (2010) Cooperative Grain Boundary Sliding and Migration Process in Nanocrystalline Solids. Physical Review Letters 105:5.
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Ilya A. Ovidko & A.G. Sheinerman. (2009) Crack Blunting through Lattice Dislocation Slip in Nanocrystalline and Ultrafine-Grained Materials. Materials Science Forum 633-634, pages 55-62.
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S.P. Wen, F. Zeng, F. Pan & Z.R. Nie. (2009) The influence of grain morphology on indentation deformation characteristic of metallic nano-multilayers. Materials Science and Engineering: A 526:1-2, pages 166-170.
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I.A. Ovid’ko & A.G. Sheinerman. (2009) Enhanced ductility of nanomaterials through optimization of grain boundary sliding and diffusion processes. Acta Materialia 57:7, pages 2217-2228.
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A.P. Gerlich & T. Shibayanagi. (2009) Grain boundary sliding during friction stir spot welding of an aluminum alloy. Scripta Materialia 60:4, pages 236-239.
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Marc Legros, Daniel S. Gianola & Kevin J. Hemker. (2008) In situ TEM observations of fast grain-boundary motion in stressed nanocrystalline aluminum films. Acta Materialia 56:14, pages 3380-3393.
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I. A. Ovid’ko & A. G. Sheĭnerman. (2008) Generation of disclination dipoles and nanoscopic cracks in deformed nanoceramic materials. Physics of the Solid State 50:6, pages 1044-1049.
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S.P. Wen, R.L. Zong, F. Zeng, Y. Gao & F. Pan. (2011) Nanoindentation investigation of the mechanical behaviors of nanoscale Ag/Cu multilayers. Journal of Materials Research 22:12, pages 3423-3431.
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A. L. Kolesnikova, I. A. Ovid’ko & A. E. Romanov. (2007) Dislocation-disclination transformations and the reverse Hall-Petch effect in nanocrystalline materials. Technical Physics Letters 33:8, pages 641-644.
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A.V. Sergueeva, N.A. Mara & A.K. Mukherjee. (2007) Plasticity at really diminished length scales. Materials Science and Engineering: A 463:1-2, pages 8-13.
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I. A. Ovid’ko & A. G. Sheinerman. (2007) Special strain hardening mechanism and nanocrack generation in nanocrystalline materials. Applied Physics Letters 90:17.
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