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Raising thermal stability of nanograins in a CuCrZr alloy by precipitates on grain boundaries 期刊论文
JOURNAL OF ALLOYS AND COMPOUNDS, 2021, 卷号: 867, 页码: 5
Authors:  Zhang, Z. Y.;  Sun, L. X.;  Tao, N. R.
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Thermal stability  Nanograins  Precipitate  Grain boundary  Zener pinning  
Anisotropic strengthening of nanotwin bundles in heterogeneous nanostructured Cu: Effect of deformation compatibility 期刊论文
ACTA MATERIALIA, 2021, 卷号: 210, 页码: 10
Authors:  Zhao, H. Z.;  You, Z. S.;  Tao, N. R.;  Lu, L.
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Heterogeneous nanostructure  Anisotropic deformation  Nanotwins  Strain partitioning  Deformation compatibility  
Enhanced high-cycle fatigue resistance of 304 austenitic stainless steel with nanotwinned grains 期刊论文
INTERNATIONAL JOURNAL OF FATIGUE, 2021, 卷号: 143, 页码: 11
Authors:  Cui, F.;  Pan, Q. S.;  Tao, N. R.;  Lu, L.
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Nanotwin  Austenitic stainless steel  Fatigue property  Cyclic deformation  Strain localization  
Cyclic strain amplitude-dependent fatigue mechanism of gradient nanograined Cu 期刊论文
ACTA MATERIALIA, 2020, 卷号: 196, 页码: 252-260
Authors:  Pan, Q. S.;  Long, J. Z.;  Jing, L. J.;  Tao, N. R.;  Lu, L.
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Gradient nanograin (GNG)  Cyclic response  Grain coarsening  Strain delocalization  Fatigue mechanism  
Cyclic strain amplitude-dependent fatigue mechanism of gradient nanograined Cu 期刊论文
ACTA MATERIALIA, 2020, 卷号: 196, 页码: 252-260
Authors:  Pan, Q. S.;  Long, J. Z.;  Jing, L. J.;  Tao, N. R.;  Lu, L.
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Gradient nanograin (GNG)  Cyclic response  Grain coarsening  Strain delocalization  Fatigue mechanism  
Nanostructures and nanoprecipitates induce high strength and high electrical conductivity in a CuCrZr alloy 期刊论文
JOURNAL OF MATERIALS SCIENCE & TECHNOLOGY, 2020, 卷号: 48, 页码: 18-22
Authors:  Zhang, Z. Y.;  Sun, L. X.;  Tao, N. R.
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CuCrZr alloy  Nanotwins  Precipitation hardening  Aging  Electrical conductivity  
Tensile ductility and deformation mechanisms of a nanotwinned 316L austenitic stainless steel 期刊论文
JOURNAL OF MATERIALS SCIENCE & TECHNOLOGY, 2020, 卷号: 36, 页码: 65-69
Authors:  Zhang, Y. Z.;  Wang, J. J.;  Tao, N. R.
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Nanotwinned  Stainless steel  Ductility  Deformation mechanism  
Revealing the deformation mechanisms of nanograins in gradient nanostructured Cu and CuAl alloys under tension 期刊论文
ACTA MATERIALIA, 2019, 卷号: 180, 页码: 231-242
Authors:  Wang, J. J.;  Tao, N. R.;  Lu, K.
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Gradient nanostructure  Tensile  Grain coarsening  Deformation twinning  CuAl alloys  
Revealing the deformation mechanisms of nanograins in gradient nanostructured Cu and CuAl alloys under tension 期刊论文
ACTA MATERIALIA, 2019, 卷号: 180, 页码: 231-242
Authors:  Wang, J. J.;  Tao, N. R.;  Lu, K.
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Gradient nanostructure  Tensile  Grain coarsening  Deformation twinning  CuAl alloys  
Deformation compatibility between nanotwinned and recrystallized grains enhances resistance to interface cracking in cyclic loaded stainless steel 期刊论文
ACTA MATERIALIA, 2019, 卷号: 165, 页码: 87-98
Authors:  Li, Q.;  Yan, F. K.;  Tao, N. R.;  Ponge, D.;  Raabe, D.;  Lu, K.
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Nanotwins  Fatigue  Interface crack  Cyclic deformation  Austenitic steel