[1] Sepehrband P, Esmaeili S. Application of recently developed approaches to microstructural characterization and yield strength modeling of aluminum alloy AA7030[J]. Materials Science and Engineering: A, 2008, 487(1): 309-315.
[2] Marlaud T, Deschamps A, Bley F, Lefebvre W, Baroux B. Evolution of precipitate microstructures during the retrogression and re-ageing heat treatment of an Al-Zn-Mg-Cu alloy[J]. Acta Materialia, 2010, 58(14): 4814-4826.
[3] Wu Q, Li D P, Ren L. Detecting milling deformation in 7075 aluminum alloy thin-walled plates using finite difference method[J]. International Journal of Advanced Manufacturing Technology, 2016, 85(5): 1291-1302.
[4] Lin Y C, Li L T, Xia Y C. Hot deformation and processing map of a typical Al–Zn–Mg–Cu alloy[J]. Journal of Alloy and Compounds, 2013, 550: 438-445.
[5] Abolfazl A, Ali K T, Kourosh K T. Recent Advances in Ageing of 7xxx Series Aluminum Alloy: A Physical Metallurgy Perspective[J]. Journal of Alloy and Compounds, 2019, 781: 945-983.
[6] Chen R R, Qin G. Composition design of high entropy alloys using the valence electron concentration to balance strength and ductility[J]. Acta Materialia, 2018, 144: 129-137.
[7] Qin G, Chen R R. A novel face-centered-cubic high-entropy alloy strengthened by nanoscale precipitates[J]. Scripta Materialia, 2019, 172: 51-55.
[8] Dey S, Gun M K, Chattoraj I. Effect of temper on the distribution of pits in AA7075 alloys[J]. Corrosion Science, 2008, 50(10): 2895-2901.
[9] Lee Y S, Koh D H, Kim H W. Improved bake-hardening response of Al-Zn-Mg-Cu alloy through pre-aging treatment[J]. Scripta Materialia, 2018, 147: 45-49.
[10] Wang D, Ni D R, Ma Z Y. Effect of pre-strain and two-step aging on microstructure and stress corrosion cracking of 7050 alloy[J]. Materials Science and Engineering: A, 2008, 494(1): 360-366.
[11] Dixit M, Mishra R S, Sankaran K K. Structure–property correlations in Al 7050 and Al 7055 high-strength aluminum alloys[J]. Materials Science and Engineering: A, 2008, 478(1): 163-172.
[12] Jiang D M, Liu Y, Liang S, Xie W L. The effects of non-isothermal aging on the strength and corrosion behavior of Al‒Zn‒Mg‒Cu alloy[J]. Journal of Alloy and Compounds, 2016, 681: 57-65.
[13] Su R M, Su J H, Qu Y D, You J H, Li R D. Retrogression on corrosion behavior of spray formed Al-7075[J]. Journal of Materials Research. 2017, 32(13): 2621-2627.
[14] Reda Y, Abdel-Karim R, Elmahallawi I. Improvements in mechanical and stress corrosion cracking properties in Al-alloy 7075 via retrogress and reaging[J]. Materials Science and Engineering: A, 2008, 485(1): 468-475.
[15] Su R M, Qu Y D, Li R D. Effect of aging treatments on the mechanical and corrosive behaviors of spray-formed 7075 alloy[J]. Journal of Materials Engineering & Performance, 2014, 23(11): 3842-3848.
[16] Nandana M S, Bhat K U, Manjunatha C M. Effect of retrogression heat treatment time on microstructure and mechanical properties of AA7010[J]. Journal of Materials Engineering & Performance, 2018, 27(4): 1628-1634.
[17] Huang L P, Li S. Influence of high-temperature pre-precipitation on local corrosion behaviors of Al–Zn–Mg alloy[J]. Scripta Materialia, 2007, 56(4): 305-308.
[18] Chen K H, Huang L P. Effect of high-temperature pre-precipitation on microstructure and properties of 7055 aluminum alloy[J]. Transactions of Nonferrous Metals Society of China, 2003, 13(4): 750-754.
[19] Li S, Chen K H. Effect of high-temperature pre-precipitation on mechanical properties and stress corrosion cracking of Al-Zn-Mg alloys[J]. Transactions of Nonferrous Metals Society of China, 2003, 13(3): 585-589.
[20] Huang L P, Chen K H, Li S. Influence of grain-boundary pre-precipitation and corrosion characteristics of inter-granular phases on corrosion behaviors of an Al–Zn–Mg–Cu alloy[J]. Materials Science and Engineering: B, 2012, 177(11): 862-868.
[21] Florando J N, Margraf J D, Reus J F, Anderson A T, McCallen R C. Modeling the effect of laser heating on the strength and failure of 7075-T6 aluminum[J]. Materials Science and Engineering: A, 2015, 640: 402-407.
[22] Ghosh K S, Mukhopadhyay S, Konar B, Mishra B. Study of aging and electrochemical behaviour of AlLiCuMg alloys[J]. Materials and Corrosion, 2013, 64(10): 890-901.
[23] Rout P K, Ghosh M M, Ghosh K S. Effect of solution pH on electrochemical and stress corrosion cracking behaviour of a 7150 Al–Zn–Mg–Cu alloy[J]. Materials Science and Engineering: A, 2014, 604: 156-165.
[24] Sha G, Cerezo A. Kinetic monte carlo simulation of clustering in an Al–Zn–Mg–Cu alloy (7050)[J]. Acta Materialia, 2005, 53(4): 907-917.
[25] Chen S Y, Chen K H, Peng G S, Jia L, Dong P X. Effect of heat treatment on strength, exfoliation corrosion and electrochemical behavior of 7085 aluminum alloy[J]. Materials Design, 2012, 35: 93-98.
[26] Zhao Y H, Liu J Z, Topping T D, Lavernia E J. Precipitation and aging phenomena in an ultrafine grained Al-Zn alloy by severe plastic deformation[J]. Journal of Alloy and Compounds, 2021, 851: 57-65.
[27] Zhang Qi, Zhu Y M, Gao X, Wu Y X, Christopher H. Training high-strength aluminum alloys to withstand fatigue[J]. Nature Communications, 2020, 11(1): 5198.
[28] Aarabi H, Alizadeh M. Improvement of microstructure and corrosion properties of AA7075 Al alloy by melt shearing process[J]. Materials Letter, 2020, 275: 128058.
[29] Zheng X Z, Castaneda H, Gao H J, Srivastava A. Synergistic effects of corrosion and slow strain rate loading on the mechanical and electrochemical response of an aluminium alloy[J]. Corrosion Science, 2019, 153: 53-61.
[30] Zhang C H, Huang G J, Cao Y. Investigation on microstructure and localized corrosion behavior in the stir zone of dissimilar friction-stir-welded AA2024/7075 joint[J]. Journal of Materials Science, 2020, 55(30): 15005-15032.