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[1]Low-temperature dynamic recrystallization occurring at a high deformation temperature during hot compression of twin-roll-cast Mg-5.51Zn-0.49Zr alloy.Scripta Materialia, 2009, 60: 403-406.
[2]Strain-induced dissolution of Cu–Mg co-clusters and dynamic recrystallization near a fatigue crack tip of an underaged Al-Cu-Mg alloy during cyclic loading at ambient temperature.Scripta Materialia, 2011, 64: 1133-1136.
[3]Mechanisms for Goss-grains induced crack deflection and enhanced fatigue crack propagation resistance in fatigue stage II of an AA2524alloy.Materials Science & Engineering A, 2015, 625: 271-277.
[4]Analysis of modulus hardening in an artificial aged Al–Cu–Mg alloy by atom probe tomography.Materials Science & Engineering A, 2015, 629: 23-28.
[5]Atom probe tomography study of Mg-dependent precipitation of Ω phase initial aged Al-Cu-Mg-Ag alloys.Materials Science & Engineering A, 2015, 637: 183-188.
[6]Effects of germanium on quench sensitivity in Al-Zn-Mg-Zr alloy.Materials & Design, 2015, 86: 679-685.
[7]Solute cluster size effect on the fatigue crack propagation resistance of an underaged Al-Cu-Mg alloy.International Journal of Fatigue, 2016, 84: 104-112.
[8]Investigation of modulus hardening of various co-clusters in aged Al-Cu-Mg-Ag alloy by atom probe tomography.Materials Science & Engineering A, 2016, 668: 234-242.
[9]Dislocation interaction with Ω phase in crept Al-Cu-Mg-Ag alloys.Materials Science & Engineering A, 651: 399-405.
[10]On the role of texture in governing fatigue crack propagation behavior of 2524 aluminum alloy.Materials Science & Engineering A, 669: 367-378.
[11]Slip band formation in plastic deformation zone at crack tip in fatigue stage II of 2xxx aluminum alloys.International Journal of Fatigue, 2016, 91: 68-78.
[12]Enhanced fatigue crack propagation resistance in a superhigh strength Al–Zn–Mg–Cu alloy by modifying RRA treatment.Materials Characterization, 2016, 118: 438-445.
[13]Enhanced fracture toughness in an annealed Al-Cu-Mg alloy by increasing Goss/Brass texture ratio.Materials Characterization, 2016, 119: 47-54.
[14]Evolution of the Brass texture in an Al-Cu-Mg alloy during hot rolling.Journal of Alloys and Compounds, 2017, 691: 786-799.
[15]Enhanced fatigue crack propagation resistance of Al-Cu-Mg alloy by intensifying Goss texture and refining Goss grains.Materials Science & Engineering A, 2017, 679: 204-214.
[16]Effect of Ag additions on the lengthening rate of Ω plates and formation of σ phase in Al-Cu-Mg alloys during thermal exposure.Materials Characterization, 2017, 123: 1-8.
[17]Effects of Ge and Ag additions on quench sensitivity and mechanical properties of an Al–Zn–Mg–Cu alloy.Materials Science & Engineering A, 2017, 682: 640-647.
[18]Analysis on the dissolution behavior of various size Cu-Mg co-clusters near a fatigue crack tip of underaged Al-Cu-Mg alloy during cyclic loading.Journal of Alloys and Compounds, 2017, 699: 119-125.
[19]Quantitative transmission electron microscopy and atom probe tomography study of Ag-dependent precipitation of Ω phase in Al-Cu-Mg alloys.Materials Science & Engineering A, 2017, 687: 8-16.
[20]Enhanced damage tolerance through reconstructing residual stress and Cu-Mg co-clusters by pre-rolling in an Al-Cu-Mg alloy.Materials Science & Engineering A, 2017, 700: 241-249.
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