Impact of cooling rate on exfoliation corrosion resistance of a Li-containing 7xxx aluminum alloy

Ke-da Jiang; Ze-xin Liao; Ming-yang Chen; Sheng-dan Liu; Jian-guo Tang

doi:10.1007/s11771-024-5702-8

Journal of Central South University ›› 2024, Vol. 31 ›› Issue (7) : 2225 -2236. DOI: 10.1007/s11771-024-5702-8

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Impact of cooling rate on exfoliation corrosion resistance of a Li-containing 7xxx aluminum alloy

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Abstract

The impact of cooling rate after solution heat treatment on exfoliation corrosion resistance of a Li-containing 7xxx aluminum alloy was investigated by accelerated immersion and electrochemical impedance spectroscopy test, optical microscope, electron backscatter diffraction and scanning transmission electron microscope. With the decrease of cooling rate from 1700 °C/s to 4 °C/s, exfoliation corrosion resistance of the aged specimens decreases with rating changing from EA to EC and the maximum corrosion depth increasing from about 169.4 µm to 632.1 µm. Exfoliation corrosion tends to develop along grain boundaries in the specimens with cooling rates higher than about 31 °C/s and along both grain boundaries and sub-grain boundaries in the specimens with lower cooling rates. The reason has been discussed based on the changes of the microstructure and microchemistry at grain boundaries and sub-grain boundaries due to slow cooling.

Keywords

7xxx aluminum alloy / cooling rate / exfoliation corrosion / microstructure

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Ke-da Jiang, Ze-xin Liao, Ming-yang Chen, Sheng-dan Liu, Jian-guo Tang. Impact of cooling rate on exfoliation corrosion resistance of a Li-containing 7xxx aluminum alloy. Journal of Central South University, 2024, 31(7): 2225-2236 DOI:10.1007/s11771-024-5702-8

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	DursunT, SoutisC. Recent developments in advanced aircraft aluminium alloys. Materials & Design (1980–2015), 2014, 56: 862-871 J]

[2]	ZhangX-s, ChenY-j, HuJ-ling. Recent advances in the development of aerospace materials. Progress in Aerospace Sciences, 2018, 97: 22-34 J]

[3]	HeK-z, LiQ, LiuS-d, et al. . Influence of prestretching on quench sensitive effect of high-strength Al-Zn-Mg-Cu-Zr alloy sheet. Journal of Central South University, 2021, 28(9): 2660-2669 J]

[4]	MaZ-m, DengY-l, LiuJ, et al. . Effect of Quenching Rate on Stress Corrosion Cracking Susceptibility of 7136 Aluminum Alloy[J]. Acta Metallurgica Sinica, 2022, 58(9): 1118-1128

[5]	ChenM-y, ZhengX, HeK-z, et al. . Local corrosion mechanism of an Al-Zn-Mg-Cu alloy in oxygenated chloride solution: Cathode activity of quenching-induced η precipitates. Corrosion Science, 2021, 191: 109743 J]

[6]	DolanG P, RobinsonJ S. Residual stress reduction in 7175-T73, 6061-T6 and 2017A-T4 aluminium alloys using quench factor analysis. Journal of Materials Processing Technology, 2004, 153–154346-351 J]

[7]	FengD, LiX-d, ZhangX-m, et al. . The novel heat treatments of aluminium alloy characterized by multistage and non-isothermal routes: A review. Journal of Central South University, 2023, 30(9): 2833-2866 J]

[8]	MaZ-m, LiuJ, YangZ-s, et al. . Effect of cooling rate and grain structure on the exfoliation corrosion susceptibility of AA 7136 alloy. Materials Characterization, 2020, 168: 110533 J]

[9]	LiuS D, ChenB, LiC B, et al. . Mechanism of low exfoliation corrosion resistance due to slow quenching in high strength aluminium alloy. Corrosion Science, 2015, 91203-212 J]

[10]	SongF-x, ZhangX-m, LiuS-d, et al. . The effect of quench rate and overageing temper on the corrosion behaviour of AA7050. Corrosion Science, 2014, 78: 276-286 J]

[11]	LiD-f, YinB-w, LeiY, et al. . Critical quenching rate for high hardness and good exfoliation corrosion resistance of Al-Zn-Mg-Cu alloy plate. Metals and Materials International, 2016, 22(2): 222-228 J]

[12]	ZhangM-h, LiuS-d, JiangJ-y, et al. . Effect of Cu content on quenching sensitivity relative to exfoliation corrosion susceptibility of Al-Zn-Mg-(Cu) alloys. Materials Characterization, 2022, 194: 112476 J]

[13]	LaverniaE J, SrivatsanT S, MohamedF A. Strength, deformation, fracture behaviour and ductility of aluminium-lithium alloys. Journal of Materials Science, 1990, 25(2): 1137-1158 J]

[14]	BaiP C, ZhouT T, LiuP Y, et al. . Effects of lithium addition on precipitation in Li-containing Al-Zn-Mg-Cu alloy. Materials Letters, 2004, 58(24): 3084-3087 J]

[15]	WeiF, LiJ-s, HuR, et al. . Influence of 1.0 wt% Li on precipitates in Al-Zn-Mg-Cu alloy. Chinese Journal of Aeronautics, 2008, 21(6): 565-570 J]

[16]	SodergrenA, LloydD J. The influence of lithium on the ageing of A 7000 series alloy. Acta Metallurgica, 1988, 36(8): 2107-2114 J]

[17]	LiuS-d, ZhongQ-m, ZhangY, et al. . Investigation of quench sensitivity of high strength Al-Zn-Mg-Cu alloys by time-temperature-properties diagrams. Materials and Design, 2010, 31(6): 3116-3120 J]

[18]	DingX-f, LiuW-h, JiangB, et al. . Effect of large pre-deformation on microstructure and mechanical properties of 7B52 laminated aluminum alloy. Journal of Alloys and Compounds, 2023, 967171749 J]

[19]	ChenY Q, XuJ B, PanS P, et al. . Effects of initial orientation on microstructure evolution of aluminum single crystals during hot deformation. Materials Science and Engineering A, 2023, 883145502 J]

[20]	JiaD-s, HeT, SongM, et al. . Microstructure evolution of 7050 Al alloy fasteners during cold upsetting after equal channel angular pressing. Journal of Central South University, 2023, 30(11): 3682-3695 J]

[21]	LiS, DongH-g, LiP, et al. . Effect of repetitious non-isothermal heat treatment on corrosion behavior of Al-Zn-Mg alloy. Corrosion Science, 2018, 131278-289 J]

[22]	DengY, YinZ-m, ZhaoK, et al. . Effects of Sc and Zr microalloying additions and aging time at 120 °C on the corrosion behaviour of an Al-Zn-Mg alloy. Corrosion Science, 2012, 65: 288-298 J]

[23]	LiuS-d, WangQ, YangZ-s, et al. . Effect of minor Ge addition on microstructure and localized corrosion behavior of Al-Zn-Mg alloy sheet. Materials Characterization, 2019, 156: 109837 J]

[24]	KeddamM, KuntzC, TakenoutiH, et al. . Exfoliation corrosion of aluminium alloys examined by electrode impedance. Electrochimica Acta, 1997, 42(1): 87-97 J]

[25]	LuX-h, HanX-l, DuZ-w, et al. . Effect of microstructure on exfoliation corrosion resistance in an Al-Zn-Mg alloy. Materials Characterization, 2018, 135167-174 J]

[26]	KnightS P, BirbilisN, MuddleB C, et al. . Correlations between intergranular stress corrosion cracking, grain-boundary microchemistry, and grain-boundary electrochemistry for Al-Zn-Mg-Cu alloys. Corrosion, 2010, 52(12): 4073-4080 J]

[27]	MarlaudT, MalkiB, HenonC, et al. . Relationship between alloy composition, microstructure and exfoliation corrosion in Al-Zn-Mg-Cu alloys. Corrosion Science, 2011, 53(10): 3139-3149 J]

[28]	PorterD A, EasterlingK E, SherifM YPhase transformations in metals and alloys, 20093Boca Raton, FL, CRC Press[M]

[29]	LiJ F, ZhengZ Q, LiS C, et al. . Simulation study on function mechanism of some precipitates in localized corrosion of Al alloys. Corrosion Science, 2007, 49(6): 2436-2449 J]

[30]	LiuS-d, LiC-b, DengY-l, et al. . Influence of grain structure on quench sensitivity relative to localized corrosion of high strength aluminum alloy. Materials Chemistry and Physics, 2015, 167: 320-329 J]

[31]	McnaughtanD, WorsfoldM, RobinsonM J. Corrosion product force measurements in the study of exfoliation and stress corrosion cracking in high strength aluminium alloys. Corrosion Science, 2003, 45(10): 2377-2389 J]