Complex Precipitation Sequences of Al-Cu-Li-(Mg) Alloys Characterized in Relation to Thermal Ageing Processes

doi:10.1007/s40195-016-0366-5

摘要/Abstract

Abstract:

The Al-Cu-Li-(Mg) alloy is a high-performance lightweight material strengthened by complex coexisting precipitates that form in the alloy upon thermal ageing. Using high-resolution (scanning) transmission electron microscopy in association with first-principles energy calculations, we systematically studied the complex coexisting precipitates in the alloys and correlated their precipitation sequences with thermal ageing processes applied. The principal results are the following: (1) eight types of precipitates can be observed in the alloy; (2) of these precipitates, the T₁-phase is most stable. The S-phase precipitates with segregated Li atoms at their interfacial edges are unexpectedly more stable than the σ-phase; (3) the T₁-phase has a characteristic precursor that plays the key role in its nucleation and growth.

Key words: Al-Cu-Li alloy, Electron microscopy, Ageing, Precipitation, Strength

. [J]. 金属学报英文版, 2016, 29(1): 94-103.

Zhen Gao, Jiang-Hua Chen†, Shi-Yun Duan, Xiu-Bo Yang, Cui-Lan Wu. Complex Precipitation Sequences of Al-Cu-Li-(Mg) Alloys Characterized in Relation to Thermal Ageing Processes[J]. Acta Metallurgica Sinica (English Letters), 2016, 29(1): 94-103.

图/表 13

Fig.1 Ageing-hardening curves of the alloy aged at different conditions: a single-step ageing, b double-step ageing

Fig.2 HAADF-STEM images of the alloy natural aged for 60 days, viewed along a <100>Al direction: a an overview of the precipitates, b a Cu-monolayer GPI zone, c a δ′-GPI-δ′ precipitate composite in an “anti-phase” relation

Fig.3 Microstructures of samples ageing at 200°C for various times: a-c 2, 12 and 72 h, respectively, viewed along <100>Al. d δ′-θ′-δ′ composite phase as indicated by arrow in b. e, f 12 and 72 h, respectively, viewed along <011>Al Summarizing our observations and that reported for the samples aged at 180°C [6], the precipitation sequence in an Al-Cu-Li-Mg alloy treated with one-step artificial ageing at about 180-200°C can be considered as follows: SSSS → GPI + δ′-GPI-δ′ + GPB + T1 → δ′-θ′-δ′ + GPB + T1 + σ + S → GPB + T1 + σ + S.

Fig.4 HAADF-STEM images of the samples treated with NA60 days plus ageing at 180°C for various times: a 0.5 h, b 28 h, c 52 h, viewed along <100>Al

Fig.5 Diameter distributions of GPI zones and δ′-GPI-δ′ composite precipitates observed a in the sample natural aged for 60 days, and b in the sample first natural aged for 60 days and then artificial-aged at 180°C for 0.5 h

Fig.6 Aberration-corrected HAADF-STEM images of different precipitates: a σ-phase in the sample two-step-aged at 180°C for 28 h, b GPB zones in the same sample as a, c GPB zones the sample two-step-aged at 180°C for 52 h, viewed along a <100>Al direction

Fig.7 HAADF-STEM images of samples treated with NA60 days plus ageing at 180°C for various times: a 28 h, b 52 h, viewed along a <011>Al direction

Fig.8 Diameter distributions of T1-precipitates in the samples first natural aged for 60 days and then artificial-aged at 180°C for 28 h a, 52 h b

Fig.9 A typical HAADF-STEM images of the NA60 days sample aged at 200°C for 0.5 h, viewed along a <100>Al direction

Fig.10 HAADF-STEM images of precipitates in the samples aged at 200°C for 6, 28 and 72 h, respectively: a-c viewed along a <100>Al direction, d-f viewed along a <011>Al direction

Fig.11 <100>Al HAADF-STEM images showing the evolution of S-precipitates in the NA60 days sample aged at 200°C: a a S2-precipitate observed at 6 h, b a S4-precipitate observed at 28 h, c a large S-precipitate observed at 72 h, in which Li atoms segregate at its interfaces with the Al-matrix

Fig.12 Diameter distributions of T1-precipitates in the samples first natural aged for 60 days and then artificial-aged at 200°C for 6 h a, 28 h b, 72 h c

Fig.13 Aberration-corrected <112>Al HAADF-STEM images revealing different atomic structures of the T1-phase in different stages of its evolution: a the initial stage of GP T1 zone; b a transitional stage from GP T1 zone to T1-precipitate; c the T1-precipitate with 1 unit cell in thickness; d the T1-precipitate with 2 unit cells in thickness

参考文献 38

[1]	T. Dursun, C. Soutis, Mater. Design 56, 862 (2014)
[2]	E.A. Prog. Aerosp. Sci. 32, 131(1996)
[3]	F.W. Gayle, F.H. Heubaum, J.R. Pickens, Scr. Metall. Mater. 24, 79(1990)
[4]	A.K. Shukla, W.A. Scr. Mater. 56, 513(2007)
[5]	A. Gaber, N. Afify, Phys. B Condens. Matter. 315, 1(2002)
[6]	B.P. Huang, Z.Q. Zheng, Acta Mater. 46, 4381(1998)
[7]	H.Y. Li, Y. Tang, Z.D. Zeng, Z.Q. Zheng, F. Zheng, Mater. Sci. Eng. A 498, 314 (2008)
[8]	X.X. Yu, Y.R. Zhang, D.F. Yin, Z.M. Yu, S.F. Li, Acta Metall. Sin. (Engl. lett.) 28, 817(2015)
[9]	C.E. April 1983 (TMS-AIME, Warrendale, 1984), p. 675
[10]	A. Guinier, Nature 142, 569 (1938)
[11]	G.D. Preston, Nature 142, 570 (1938)
[12]	T.J. Konno, K. Hiraga, M. Kawasaki, Scr. Mater. 44, 2303(2001)
[13]	J. Silcock, T. Heal, H. Hardy, J. Inst. Met. 82, 239(1954)
[14]	S.M. Kumaran, N. Priyadharsini, V. Rajendran, T. Jayakumar, P. Palanichamy, P. Shankar, B. Raj, Mater. Sci. Eng. A 435-436, 29(2006)
[15]	J.M. Silcock, J. Inst. Met. 88, 357 (1959-60)
[16]	B. Decreus, A. Deschamps, F. De Geuser, P. Donnadieu, C. Sigli, M. Weyland, Acta Mater. 61, 2207(2013)
[17]	R. Yoshimura, T.J. Konno, E. Abe, K. Hiraga, Acta Mater. 51, 2891(2003)
[18]	R.D. Schueller, A.K. Sachdev, F.E. Wawner, Scr. Metall. Mater. 27, 1289(1992)
[19]	Z.R. Pan, Z.Q. Zheng, Z.Q. Liao, S.C. Li, Mater. Lett. 64, 942(2010)
[20]	H.K. Hardy, J.M. Silock, J. Inst. Met. 423 (1955-1956)
[21]	S. Van Smaalen, A. Meetsma, J.L. J. Solid State Chem. 85, 293(1990)
[22]	C. Dwyer, M. Weyland, L.Y. Chang, B.C. Muddle, Appl. Phys. Lett. 98, 201901-201909 (2011)
[23]	P. Donnadieu, Y. Shao, F. De Geuser, G.A. Botton, S. Lazar, M. Cheynet, Acta Mater. 59, 462(2011)
[24]	H. Suzuki, M. Kanno, N. Hayashi, J. Jpn. Inst. Light. Met. 32, 88(1982)
[25]	J.C. Huang, A.J. Ardell, Mater. Sci. Technol. 3, 176(1987)
[26]	B. Noble, G.E. Thompson, Metal. Sci. J. 6, 167(1972)
[27]	K.S. Kumar, S.A. Brown, J.R. Pickens, Acta Mater. 44, 1899(1996)
[28]	M.J. Yin, J.H. Chen, S.B. Wang, Z.R. Liu, L.M. Cha, S.Y. Duan, C.L. Wu, Trans. Nonferr. Met. Soc. China 26, 1 (2016)
[29]	B. Decreus, A. Deschamps, Adv. Eng. Mater. 15, 1082(2013)
[30]	P.D. Nellist, S.J. Pennycook, Ultramicroscopy 78, 111 (1999)
[31]	S. Hillyard, J. Silcox, Ultramicroscopy 58, 6 (1995)
[32]	G. Kresse, J. Furthmüller, Phys. Rev. B 54, 11169 (1996)
[33]	J.P. Perdew, J. Chevary, S. Vosko, K.A. Jackson, M.R. Pederson, D. Singh, C. Fiolhais, Phys. Rev. B 46, 6671 (1992)
[34]	J.P. Perdew, Y. Wang, Phys. Rev. B 45, 13244 (1992)
[35]	H.J. Monkhorst, J.D. Pack, Phys. Rev. B 13, 5188 (1976)
[36]	Z.R. Liu, J.H. Chen, S.B. Wang, D.W. Yuan, M.J. Yin, C.L. Wu, Acta Mater. 59, 7396(2011)
[37]	S.B. Wang, J.H. Chen, M.J. Yin, Z.R. Liu, D.W. Yuan, J.Z. Liu, C.H. Liu, C.L. Wu, Acta Mater. 60, 6573(2012)
[38]	Z. Gao, J.Z. Liu, J.H. Chen, S.Y. Duan, Z.R. Liu, W.Q. Ming, C.L. Wu, J. Alloys Compd. 624, 22(2015)