A review of creep-resistant aluminum alloys: Control of primary strengthening phases

doi:10.1016/j.metadv.2026.02.024

Abstract

Abstract:

Aluminum alloys have become critical lightweight materials in aerospace, defense equipment, and new energy vehicles due to their advantages such as low density and high specific strength. With equipment advancing toward high performance and integration, more stringent demands are imposed on the high-temperature creep resistance of aluminum alloy structural components. This review proposes optimization strategies for creep resistance based on the control of primary strengthening phases, systematically provides a comprehensive discussion of representative systems (Al-Cu, Al-Si, Al-RE, and AMCs) for different strengthening phases, incorporating perspectives such as processing techniques, microalloying, and multidimensional design. This review not only clarifies and substantiates the optimization strategies based on the control of strengthening phases, but also identifies a universal design principle: constructing strengthening phases featuring higher thermal stability, increased content, refined structure, and multi-level barriers. Ultimately, based on these strategies and principles, forward-looking research directions warranting further in-depth investigation for future extreme service conditions are presented.

Key words: Aluminum alloys, Creep resistance, Strengthening phases, Optimization strategies, Creep strengthening mechanisms

Qianxi Zhang, Bo Hu, Hong Gao, Wanqi Huang, Zhipeng Xiao, Jun Jiang, Wanzhang Yang, Bensong Chen, Dejiang Li, Xiaoqin Zeng. A review of creep-resistant aluminum alloys: Control of primary strengthening phases[J]. Metals Advances, 2026, 42: 66-85.

Figures/Tables 25

References 113

[1]	S.S. Li, X. Yue, Q.Y. Li, H.L. Peng, B.X. Dong, T.S. Liu, H.Y. Yang, J. Fan, S.L. Shu, F. Qiu, J. Mater. Res. Technol. 27 (2023) 944-983.
[2]	L. Setlak, R. Kowalik, T. Lusiak, Materials 14 (2021) 4812.
[3]	Y.C. Gao, B.X. Dong, H.Y. Yang, X.Y. Yao, S.L. Shu, J. Kang, J. Meng, C.J. Luo, C.G. Wang, K. Cao, J. Mater. Res. Technol. 32 (2024) 1868-1900.
[4]	S. Zhang, Y. Zhang, M. Chen, Y. Wang, Q. Cui, R. Wu, D. Arola, D. Zhang, Appl. Math. Mech. 39 (2018) 967-980. DOI
[5]	K.E. Knipling, D.C. Dunand, D.N. Seidman, Int. J. Mater. Res. 97 (2022) 246-265. DOI URL
[6]	A.W. Zhu, B.M. Gable, G.J. Shiflet, E.J. Starke, Mater. Sci. Forum 396 (2002) 21-30.
[7]	S. Zhang, X. Wu, M. Yang, P. Ren, X. Meng, Appl. Sci. 13 (2023) 6456. DOI URL
[8]	S. Kovacevic, S.D. Mesarovic, Int. J. Solids Struct. 239 (2022) 111440.
[9]	Y. Gai, R. Zhang, F. Wang, Z. Zhou, X. Tao, S. Lyu, X. Xie, C. Cui, J. Qu, T. Zhu, Acta Metall. Sin. -Engl. Lett. 38 (2025) 2102-2114.
[10]	Y. Han, J. Sun, J. Sun, G. Zu, W. Zhu, X. Ran, Acta Metall. Sin. -Engl. Lett. 34 (2021) 789-801.
[11]	M.E. Kassner, Fundamentals of Creep in Metals and Alloys, second ed., Elsevier, Chantilly, 2009, pp. 249-259.
[12]	F.R. Nabarro, Mater. Sci. Eng. A 387 (2004) 659-664.
[13]	R. Coble, J. Appl. Phys. 34 (1963) 1679-1682.
[14]	O.A. Ruano, J. Wadsworth, J. Wolfenstine, O. Sherby, Mater. Sci. Eng. A 165 (1993) 133-141. DOI URL
[15]	T. Dessolier, P. Lhuissier, F. Roussel-Dherbey, F. Charlot, C. Josserond, J.J. Blandin, G. Martin, Mater. Sci. Eng. A 775 (2020) 138957. DOI URL
[16]	V.T. Ha, W.S. Jung, Mater. Sci. Eng. A 558 (2012) 103-111. DOI URL
[17]	W. Yu, L. Zhan, Y. Xu, K. Chen, Y. Yang, L. Xu, N. Peng, B. Ma, C. Liu, Z. Chen, J. Mater. Res. Technol. 19 (2022) 1343-1354.
[18]	T. Kaji, J. Cadek, H. Oikawa, Acta Metall. 36 (1988) 2259-2266. DOI URL
[19]	J.P. Poirier, Acta Metall. 26 (1978) 629-637. DOI URL
[20]	Y.Q. Jiang, Y. Lin, C. Phaniraj, Y.C. Xia, H.M. Zhou, High Temp. Mater. Processes 32 (2013) 533-540. DOI URL
[21]	Q. Zhang, X. Huang, R. Guo, D. Chen, Materials 15 (2022) 8117.
[22]	P.T. Summers, Y. Chen, C.M. Rippe, B. Allen, A.P. Mouritz, S.W. Case, B.Y. Lattimer, Fire Sci. Rev. 4 (2015) 1-36. DOI URL
[23]	R.K. Penny, D.L. Marriott, Design for creep, second ed., Springer Science & Business Media, Dordrecht, 1995, pp. 249-285.
[24]	G. Hu, P. Wang, D. Li, Y. Li, Acta Metall. Sin. -Engl. Lett. 33 (2020) 1455-1465.
[25]	B. Wilshire, M. Whittaker, Acta Mater. 57 (2009) 4115-4124. DOI URL
[26]	S. Bahl, J.U. Rakhmonov, C. Kenel, D.C. Dunand, A. Shyam, Mater. Sci. Eng. A 840 (2022) 142946. DOI URL
[27]	O.D. Sherby, E.M. Taleff, Mater. Sci. Eng. A 322 (2002) 89-99. DOI URL
[28]	N. Chawla, K.K. Chawla, Metal Matrix Composites, second ed., Springer Science & Business Media, New York, 2013, pp. 283-304.
[29]	J. Kohout, Molecules 26 (2021) 7162.
[30]	Y. Zhang, H.Y. Jing, L.Y. Xu, Y.D. Han, L. Zhao, X.S. Xie, Q.H. Zhu, Acta Metall. Sin. -Engl. Lett. 32 (2019) 638.
[31]	P.K. Chaudhury, F.A. Mohamed, Metall. Trans. A 18 (1987) 2105-2114. DOI URL
[32]	G. Malakondaiah, R. Rao, Def. Sci. J. 35 (1985) 201-217. DOI URL
[33]	F. Wang, J.J. Bhattacharyya, S.R. Agnew, Mater. Sci. Eng. A 666 (2016) 114-122. DOI URL
[34]	C.K.L. Davies, P. Nash, R.N. Stevens, Acta Metall. 28 (1980) 179-189. DOI URL
[35]	M. Yi, P. Zhang, S. Deng, H. Xue, C. Yang, F. Liu, B. Chen, S. Wu, H. Lu, Z. Tan, J. Zhang, Y. Peng, G. Liu, L. He, J. Sun, Acta Mater. 276 (2024) 120133. DOI URL
[36]	X. Wu, Q. Yan, G. Lu, P. Huang, Chin. J. Nonferrous Met. 31 (2021) 2339-2347.
[37]	A. Orozco-Caballero, S.K. Menon, C.M. Cepeda-Jiménez, P. Hidalgo-Manrique, T.R. Mcnelley, O.A. Ruano, F. Carreño, Mater. Sci. Eng. A 612 (2014) 162-171. DOI URL
[38]	J.U. Rakhmonov, B. Milligan, S. Bahl, D. Ma, A. Shyam, D.C. Dunand, Acta Mater. 250 (2023) 118886. DOI URL
[39]	Z.Y. Ma, S.C. Tjong, Compos. Sci. Technol. 61 (2001) 771-786. DOI URL
[40]	P. Chen, W. Chen, J. Chen, Z. Chen, Y. Tang, G. Liu, B. Huang, Z. Zhang, Acta Metall. Sin. -Engl. Lett. 37 (2024) 855-871.
[41]	M. Su, X. Yuan, C. Yue, W. Zheng, Y. Wang, J. Kang, Acta Metall. Sin. -Engl. Lett. 36 (2023) 103-117.
[42]	K. García-Aguirre, J.T. Holguín-Momaca, M. Ruiz-Esparza-Rodriguez, J. Guía- Tello, C. Garay-Reyes, I. Estrada-Guel, R. Martínez-Sánchez, Microsc. Microanal. 28 (2022) 2854-2856. DOI URL
[43]	S. Mondol, U. Bansal, P. Dhanalakshmi, S. Makineni, A. Mandal, K. Chattopadhyay, J. Alloy. Compd. 921 (2022) 166136. DOI URL
[44]	B.K. Milligan, S. Roy, C.S. Hawkins, L.F. Allard, A. Shyam, Mater. Sci. Eng. A 772 (2020) 138697. DOI URL
[45]	S. Wu, C. Yang, P. Zhang, H. Xue, Y. Gao, Y. Wang, R. Wang, J. Zhang, G. Liu, J. Sun, Int. J. Miner. Metall. Mater. 31 (2024) 1098-1114.
[46]	J. Jae-Ho, N. Dae-Geun, P. Yong-Ho, P. Ik-Min, Trans. Nonferrous Met. Soc. China 23 (2013) 631-635. DOI URL
[47]	Z. Li, Y. Zhang, J. Zhang, X. Chen, S. Chen, L. Cui, S. Han, Acta Metall. Sin. -Engl. Lett. 37 (2024) 1501-1522.
[48]	D. Pu, X. Chen, J. Wang, J. Tan, J. Li, H. Yang, B. Feng, K. Zheng, F. Pan, Acta Metall. Sin. -Engl. Lett. 37 (2024) 401-406.
[49]	R.N. Lumley, A.J. Morton, I.J. Polmear, Acta Mater. 50 (2002) 3597-3608. DOI URL
[50]	B. Zhang, S. Zhang, H. Du, Z. Yao, X.S. Kong, X. Tao, Adv. Eng. Mater. 24 (2022) 2101293. DOI URL
[51]	A. Rodríguez-Veiga, B. Bellón, I. Papadimitriou, G. Esteban-Manzanares, I. Sabirov, J. Llorca, J. Alloy. Compd. 757 (2018) 504-519. DOI URL
[52]	C. Yang, L. Cao, Y. Gao, P. Cheng, P. Zhang, J. Kuang, J. Zhang, G. Liu, J. Sun, Mater. Des. 186 (2020) 108309. DOI URL
[53]	Y.H. Gao, C. Yang, J.Y. Zhang, L.F. Cao, G. Liu, J. Sun, E. Ma, Mater. Res. Lett. 7 (2019) 18-25. DOI
[54]	J.U. Rakhmonov, S. Bahl, A. Shyam, D.C. Dunand, Acta Mater. 228 (2022) 117788. DOI URL
[55]	Z. Bai, F. Qiu, X. Wu, Y. Liu, Q. Jiang, Mater. Charact. 86 (2013) 185-189. DOI URL
[56]	D.M. Yao, Laws and Mechanisms for the Effects of La, Pr on the Microstructure and Elevated Temperature Properties of the Cast Al-Cu Alloys, Ph.D. Thesis, Jilin University, 2012.
[57]	J. Mei, Y. Han, G. Zu, W. Zhu, Y. Zhao, H. Chen, X. Ran, Acta Metall. Sin. -Engl. Lett. 35 (2022) 1665-1672.
[58]	J. Dong, J. Jiang, Y. Wang, M. Huang, J. Cui, T. Song, Acta Metall. Sin. -Engl. Lett. 38 (2025) 449-464.
[59]	C. Han, Y. Wu, H. Huang, C. Chen, H. Liu, J. Jiang, A. Ma, J. Bai, H. Liao, Acta Metall. Sin. -Engl. Lett. 37 (2024) 2094-2105.
[60]	S.S. Dash, D. Chen, Materials 13 (2023) 609.
[61]	H.E. Hu, X. Wang, L. Deng, Mater. Sci. Eng. A 576 (2013) 45-51. DOI URL
[62]	J. Rakhmonov, G. Timelli, F. Bonollo, Adv. Eng. Mater. 18 (2016) 1096-1105. DOI URL
[63]	C. Han, Y. Wu, H. Huang, C. Chen, H. Liu, J. Jiang, A. Ma, J. Bai, H. Liao, Acta Metall. Sin. -Engl. Lett. 37 (2024) 2094-2105.
[64]	M. Javidani, D. Larouche, Int. Mater. Rev. 59 (2014) 132-158. DOI URL
[65]	J.A. Glerum, J.E. Mogonye, D.C. Dunand, Mater. Sci. Eng. A 843 (2022) 143075. DOI URL
[66]	S.I. Fujikawa, K.I. Hirano, Y. Fukushima, Metall. Trans. A 9 (1978) 1811-1815. DOI URL
[67]	Y. Cao, X. Lin, Q.Z. Wang, S.Q. Shi, L. Ma, N. Kang, W.D. Huang, J. Mater. Sci. Technol. 62 (2021) 162-172.
[68]	S.I. Fujikawa, Y. Oyobiki, K.I. Hirano, J. Japan Inst. Light Metals 29 (1979) 331-339.
[69]	M. Yıldırım, D. Özyürek, Mater. Des. 51 (2013) 767-774. DOI URL
[70]	A.R. Farkoosh, M. Pekguleryuz, Mater. Sci. Eng. A 621 (2015) 277-286. DOI URL
[71]	A.R. Farkoosh, X. Grant Chen, M. Pekguleryuz, Mater. Sci. Eng. A 627 (2015) 127-138. DOI URL
[72]	H. Huang, W. Li, C. Hu, L. Ding, Z. Jia, N. Zhou, Mater. Sci. Eng. A 836 (2022) 142570. DOI URL
[73]	J. Li, X. Wang, T. Ludwig, Y. Tsunekawa, L. Arnberg, J. Jiang, P. Schumacher, Acta Mater. 84 (2015) 153-163. DOI URL
[74]	A. Mazahery, M.O. Shabani, JOM 66 (2014) 726-738.
[75]	Q. Zhang, C. Zheng, W. Han, Acta Metall. Sin. 17 (1981) 130-241.
[76]	Y. Chen, G. Lu, Q. Yan, P. Huang, P. Xu, P. Mao, Z. Zhou, J. Mech. Eng. 59 (2023) 186-195.
[77]	B. Hu, W.J. Zhu, Z.X. Li, S.B. Lee, D.J. Li, X.Q. Zeng, Y.S. Choi, J. Magnes. Alloy. 11 (2023) 2299-2311.
[78]	C. Yue, B. Zheng, M. Su, Y. Wang, X. Zuo, Y. Wang, X. Yuan, Acta Metall. Sin. -Engl. Lett. 37 (2024) 939-952.
[79]	G. Wang, W. Sun, D. Xu, M. Zhang, L. Niu, Y. Wang, Mater. Res. Bull. 184 (2025) 113227. DOI URL
[80]	Z. Bai, B. Qin, J. Phys.: Conf. Ser.1885 (2021) 32029.
[81]	Y.X. Li, F.Q. Meng, R. Yuan, G.Q. Huang, D.B. Sun, Acta Metall. Sin. -Engl. Lett. 35 (2022) 157-162.
[82]	Y. Liu, R.A. Michi, D.C. Dunand, Mater. Sci. Eng. A 767 (2019) 138440. DOI URL
[83]	C. Zhang, P. Peng, H. Lv, H. Gao, Y. Wang, J. Wang, B. Sun, J. Mater. Res. Technol. 18 (2022) 693-704.
[84]	D.S. Ng, D.C. Dunand, Mater. Sci. Eng. A 786 (2020) 139398. DOI URL
[85]	Q. Wei, Effect of Si Addition on the Microstructure and Creep Properties of Cast Al- Ce Alloy, Master’s Thesis, Central South University, 2023.
[86]	R.A. Michi, K. Sisco, S. Bahl, Y. Yang, J.D. Poplawsky, L.F. Allard, R.R. Dehoff, A. Plotkowski, A. Shyam, Acta Mater. 227 (2022) 117699. DOI URL
[87]	C.N. Ekaputra, J.U. Rakhmonov, E. Senvardarli, D. Weiss, J.-E. Mogonye, D.C. Dunand, Acta Mater. 266 (2024) 119683. DOI URL
[88]	C. Zhang, Y. Jiang, X. Guo, K. Song, Acta Metall. Sin. -Engl. Lett. 33 (2020) 1627-1634.
[89]	K. Yan, Z.W. Chen, Y.N. Zhao, C.C. Ren, W.J. Lu, A.W. Aldeen, J. Alloy. Compd. 861 (2021) 158491. DOI URL
[90]	D.N. Seidman, E.A. Marquis, D.C. Dunand, Acta Mater. 50 (2002) 4021-4035. DOI URL
[91]	M.E. Van Dalen, D.C. Dunand, D.N. Seidman, Acta Mater. 59 (2011) 5224-5237. DOI URL
[92]	N.Q. Vo, D.C. Dunand, D.N. Seidman, Acta Mater. 63 (2014) 73-85. DOI URL
[93]	Y. Zan, X. Lei, J. Zhang, D. Wang, Q. Wang, B. Xiao, Z. Ma, Acta Metall. Sin. -Engl. Lett. 35 (2022) 2007-2013.
[94]	L. Li, D. Zhou, K. Zhao, L. Jiang, H. Kang, E. Guo, F. Mao, Z. Chen, T. Wang, Acta Metall. Sin. -Engl. Lett. 37 (2024) 1421-1437.
[95]	Y.N. Zan, Y.T. Zhou, X.N. Li, G.N. Ma, Z.Y. Liu, Q.Z. Wang, D. Wang, B.L. Xiao, Z.Y. Ma, Acta Metall. Sin. -Engl. Lett. 33 (2020) 913-921.
[96]	S. Asif, C. Kodanda, M. Nagaral, V. Auradi, Composites 1 (2018) 2.
[97]	D.V. Dudina, B.B. Bokhonov, A.K. Mukherjee, J. Ceram. Soc. Jpn. 124 (2016) 289-295. DOI URL
[98]	M. Jagannatham, P. Chandran, S. Sankaran, P. Haridoss, N. Nayan, S.R. Bakshi,Carbon 160 (2020) 14-44.
[99]	M. Wang, J. Shen, B. Chen, Y. Wang, J. Umeda, K. Kondoh, Y. Li, Ceram. Int. 48 (2022) 10299-10310. DOI URL
[100]	L. Shan, C. Tan, X. Shen, S. Ramesh, R. Kolahchi, M. Hajmohammad, D. Rajak, Materials 15 (2022) 8959.
[101]	H. Choi, D. Bae, Scr. Mater. 65 (2011) 194-197. DOI URL
[102]	M.F. Moreno, C.J.G. Oliver, Mater. Sci. Eng. A 418 (2006) 172-181. DOI URL
[103]	Y. Zheng, Y. Wang, B. Li, Y. Bai, H. Xu, L. Liu, B. Song, X. Li, Mater. Charact. (2025) 115182.
[104]	K. Kawabata, E. Sato, K. Kuribayashi, Acta Mater. 50 (2002) 3465-3474. DOI URL
[105]	T. Wang, X. Kai, L. Huang, Q. Peng, K. Sun, Y. Zhao, J. Alloy. Compd. 981 (2024) 173662. DOI URL
[106]	M. Huang, X. Li, H. Yi, N. Ma, H. Wang, J. Alloy. Compd. 389 (2005) 275-280. DOI URL
[107]	F. Ji, M.Z. Ma, A.J. Song, W.G. Zhang, H.T. Zong, S.X. Liang, Y. Osamu, R.P. Liu, Mater. Sci. Eng. A 506 (2009) 58-62. DOI URL
[108]	A. Knowles, X. Jiang, M. Galano, F. Audebert, J. Alloy. Compd. 615 (2014) S401-S405. DOI URL
[109]	W. Qian, X. Kai, R. Tao, R. Cao, C. Guan, Y. Zhao, Mater. Charact. 196 (2023) 112620. DOI URL
[110]	R. Tao, Y. Zhao, X. Kai, Z. Zhao, R. Ding, L. Liang, W. Xu, J. Alloy. Compd. 754 (2018) 114-123. DOI URL
[111]	W.S. Tian, Q.L. Zhao, Q.Q. Zhang, F. Qiu, Q.C. Jiang, Mater. Sci. Eng. A 700 (2017) 42-48. DOI URL
[112]	W.S. Tian, Q.L. Zhao, R. Geng, F. Qiu, Q.C. Jiang, Mater. Sci. Eng. A 713 (2018) 190-194. DOI URL
[113]	B.X. Dong, Q.Y. Li, S.L. Shu, X.Z. Duan, Q. Zou, X. Han, H.Y. Yang, F. Qiu, Q.C. Jiang, Tribol. Int. 177 (2023) 107943. DOI URL

Category	Factors	Principal mechanisms	Representative equations and key parameters	Critical impacts
External environmental factors	Temperature [29], [30]	Increased atomic diffusion; reduced interfacial and phase thermal stability	$D=D_{0} \mathrm{e}^{-Q / R T}$ $\dot{\varepsilon}_{\mathrm{c}}=A \sigma^{n} \mathrm{e}^{-Q / R T}$ temperature ($T$), activation energy ($Q$)	At high temperature and low stress, diffusion/GBS mechanisms dominate; increasing temperature aggravates strengthening phases coarsening and solid-solution degradation.
External environmental factors	Stress [30]	Enhanced dislocation glide and climb; with temperature, co-controls steady-state creep	$\dot{\varepsilon}_{\mathrm{c}}=A \sigma^{n} \mathrm{e}^{-Q / R T}$ stress ($σ$), stress exponent ($n$)	At higher stresses, creep is usually dislocation-controlled; when the stress exponent is large, the steady-state creep rate is highly stress-sensitive.
Intrinsic material factors	Solid solution [31]	Solute drag; cottrell-atmosphere	$\begin{array}{l} \gamma_{\mathrm{g}} \\ =\frac{4}{\begin{array}{l} A_{\mathrm{C}-\mathrm{J}}+A_{\mathrm{P}}+A_{\mathrm{S}}+A_{\mathrm{Sn}} \\ +A_{\mathrm{APB}} \end{array}} G\left(\frac{\tau}{G}\right)^{3} \end{array}$	Its contribution is more pronounced at low-intermediate temperatures; it weakens at high temperature due to rapid solute diffusion.
	Grains [32]	Impedes dislocation motion and grain boundary sliding	$\dot{\varepsilon}_{\mathrm{NH}}=A_{\mathrm{NH}} \frac{\Omega D_{\mathrm{v}} \sigma}{d^{2} k T}$ $\dot{\varepsilon}_{\mathrm{Co}}=A_{\mathrm{Co}} \frac{w \cap D_{\mathrm{B}} \sigma}{d^{3} k T}$	At higher temperatures, grain refinement is markedly detrimental to creep.
	Intragranular precipitates [33], [34]	Orowan bypassing; precipitate shearing	∆τ=Gb2π1−v1λln(dpr0) rt3−r03=K	At low-intermediate temperatures, intragranular precipitates are critical in dislocation-controlled creep; their benefit increases with high thermal stability.
	GB strengthening phases [35]	Load transfer; GBS suppression	$\begin{array}{l} \Delta \tau \\ =\frac{G b}{2 \pi \sqrt{1-v}} \frac{1}{\lambda} \ln \left(\frac{d_{p}}{t_{0}}\right) \end{array}$ volume fraction ($f_i$), aspect ratio ($s$)	Heat-resistant strengthening phases determine long-term stability at elevated temperatures.

Category	Factors	Principal mechanisms	Representative equations and key parameters	Critical impacts
External environmental factors	Temperature [29], [30]	Increased atomic diffusion; reduced interfacial and phase thermal stability	$D=D_{0} \mathrm{e}^{-Q / R T}$ $\dot{\varepsilon}_{\mathrm{c}}=A \sigma^{n} \mathrm{e}^{-Q / R T}$ temperature ($T$), activation energy ($Q$)	At high temperature and low stress, diffusion/GBS mechanisms dominate; increasing temperature aggravates strengthening phases coarsening and solid-solution degradation.
External environmental factors	Stress [30]	Enhanced dislocation glide and climb; with temperature, co-controls steady-state creep	$\dot{\varepsilon}_{\mathrm{c}}=A \sigma^{n} \mathrm{e}^{-Q / R T}$ stress ($σ$), stress exponent ($n$)	At higher stresses, creep is usually dislocation-controlled; when the stress exponent is large, the steady-state creep rate is highly stress-sensitive.
Intrinsic material factors	Solid solution [31]	Solute drag; cottrell-atmosphere	$\begin{array}{l} \gamma_{\mathrm{g}} \\ =\frac{4}{\begin{array}{l} A_{\mathrm{C}-\mathrm{J}}+A_{\mathrm{P}}+A_{\mathrm{S}}+A_{\mathrm{Sn}} \\ +A_{\mathrm{APB}} \end{array}} G\left(\frac{\tau}{G}\right)^{3} \end{array}$	Its contribution is more pronounced at low-intermediate temperatures; it weakens at high temperature due to rapid solute diffusion.
	Grains [32]	Impedes dislocation motion and grain boundary sliding	$\dot{\varepsilon}_{\mathrm{NH}}=A_{\mathrm{NH}} \frac{\Omega D_{\mathrm{v}} \sigma}{d^{2} k T}$ $\dot{\varepsilon}_{\mathrm{Co}}=A_{\mathrm{Co}} \frac{w \cap D_{\mathrm{B}} \sigma}{d^{3} k T}$	At higher temperatures, grain refinement is markedly detrimental to creep.
	Intragranular precipitates [33], [34]	Orowan bypassing; precipitate shearing	∆τ=Gb2π1−v1λln(dpr0) rt3−r03=K	At low-intermediate temperatures, intragranular precipitates are critical in dislocation-controlled creep; their benefit increases with high thermal stability.
	GB strengthening phases [35]	Load transfer; GBS suppression	$\begin{array}{l} \Delta \tau \\ =\frac{G b}{2 \pi \sqrt{1-v}} \frac{1}{\lambda} \ln \left(\frac{d_{p}}{t_{0}}\right) \end{array}$ volume fraction ($f_i$), aspect ratio ($s$)	Heat-resistant strengthening phases determine long-term stability at elevated temperatures.

Alloy code	Composition (wt%) and processing	Heat treatment	Creep conditions	Creep rate (s⁻¹)	n	Q (kJ/mol)	σth (MPa)	Creep mechanism	Strengthening mechanism
Al-Cu-Mg-Ag [49]	5.6Cu-0.45Mg-0.45Ag (gravity cast)	T6	150 °C, 300 MPa	1.12 × 10⁻⁹	\	\		Dislocation viscous glide and climb	Under-aging retains more θ′ precipitate
Al-Cu-Mg-Ag [49]	5.6Cu-0.45Mg-0.45Ag (gravity cast)	UA	150 °C, 300 MPa	4.83 × 10⁻¹⁰	4.3	\	\	Dislocation viscous glide and climb	Under-aging retains more θ′ precipitate
Al-Cu-Mg [50]	3Cu-0.46Mg (rolling)	UA	185 °C, 150 MPa	5.33 × 10⁻⁷	4.17	232	79	Dislocation viscous glide and climb	Under-aging and Cu/Mg segregation
		PA	185 °C, 150 MPa	∼6.5 × 10⁻¹⁰	3.96	\	87
		OA	185 °C, 150 MPa	2.39 × 10⁻⁶	4.01	\	140
Al-Cu-Sc [53]	2.5Cu-0.3Sc (gravity cast)	RR	300 °C, 30 MPa	∼1 × 10⁻⁹	7.97	\	\	Dislocation climb	Sc addition refines θ′ precipitate and enhances thermal stability via surface segregation
Al-Cu-Sc [53]	2.5Cu-0.3Sc (gravity cast)	AA	300 °C, 30 MPa	∼2 × 10⁻⁸	8.34	\	\	Dislocation climb
206 [44]	4.5Cu-0.3Mg-0.23Mn (gravity cast)	T5	300 °C, 40 MPa	7 × 10⁻⁶	22	\	\	Power-law breakdown	Alloying (Mn/Zr/Ni/Co) improves θ′ precipitate stability
Al-7Cu [44]	6.4Cu-0.19Mn-0.13Zr (gravity cast, small grain)	T5	300 °C, 40 MPa	5 × 10⁻⁸	5.0	\		Dislocation climb
Al-7Cu [44]	6.4Cu-0.19Mn-0.13Zr (gravity cast, large grain)	T5	300 °C, 40 MPa	7 × 10⁻⁹	4.2	\	\	Dislocation climb
RR350 [44]	4.8Cu-0.19Mn-0.17Zr-1.2Ni-0.26Co-0.21Ti (gravity cast)	T5	300 °C, 60 MPa	∼1.5 × 10⁻⁸	7.2	\	\	Dislocation climb
Al-Cu [55]	6.0Cu-0.15Mn-0.25Ti-0.13V-0.13Zr (gravity cast)	T6	200 °C, 80 MPa	2.18 × 10⁻⁵	18.1	166	\	Dislocation climb	Pr reduces θ′ size, increases density and thermal stability
Al-Cu [55]	+0.3Pr (gravity cast)	T6	200 °C, 80 MPa	5.17 × 10⁻⁶	19.6	216	\	Dislocation climb	Pr reduces θ′ size, increases density and thermal stability
Al-Cu [56]	5.5Cu-0.45Mn-0.3Ti-0.2V-0.2Cd-0.15Zr (gravity cast)	T6	200 °C, 80 MPa	2.18 × 10⁻⁵	18.1	166	45	Dislocation climb	Rare earth compounds pin grain boundaries and stabilize θ′ precipitate
	+0.3Pr (gravity cast)	T6	200 °C, 80 MPa	5.17 × 10⁻⁶	19.6	216	51
	+0.3La (gravity cast)	T6	200 °C, 80 MPa	4.47 × 10⁻⁶	20.3	260	55
	+0.2La and 0.1Pr (gravity cast)	T6	200 °C, 80 MPa	4.11 × 10⁻⁶	21.7	266	\

Alloy code	Composition (wt%) and processing	Heat treatment	Creep conditions	Creep rate (s⁻¹)	n	Q (kJ/mol)	σth (MPa)	Creep mechanism	Strengthening mechanism
Al-Cu-Mg-Ag [49]	5.6Cu-0.45Mg-0.45Ag (gravity cast)	T6	150 °C, 300 MPa	1.12 × 10⁻⁹	\	\		Dislocation viscous glide and climb	Under-aging retains more θ′ precipitate
Al-Cu-Mg-Ag [49]	5.6Cu-0.45Mg-0.45Ag (gravity cast)	UA	150 °C, 300 MPa	4.83 × 10⁻¹⁰	4.3	\	\	Dislocation viscous glide and climb	Under-aging retains more θ′ precipitate
Al-Cu-Mg [50]	3Cu-0.46Mg (rolling)	UA	185 °C, 150 MPa	5.33 × 10⁻⁷	4.17	232	79	Dislocation viscous glide and climb	Under-aging and Cu/Mg segregation
		PA	185 °C, 150 MPa	∼6.5 × 10⁻¹⁰	3.96	\	87
		OA	185 °C, 150 MPa	2.39 × 10⁻⁶	4.01	\	140
Al-Cu-Sc [53]	2.5Cu-0.3Sc (gravity cast)	RR	300 °C, 30 MPa	∼1 × 10⁻⁹	7.97	\	\	Dislocation climb	Sc addition refines θ′ precipitate and enhances thermal stability via surface segregation
Al-Cu-Sc [53]	2.5Cu-0.3Sc (gravity cast)	AA	300 °C, 30 MPa	∼2 × 10⁻⁸	8.34	\	\	Dislocation climb
206 [44]	4.5Cu-0.3Mg-0.23Mn (gravity cast)	T5	300 °C, 40 MPa	7 × 10⁻⁶	22	\	\	Power-law breakdown	Alloying (Mn/Zr/Ni/Co) improves θ′ precipitate stability
Al-7Cu [44]	6.4Cu-0.19Mn-0.13Zr (gravity cast, small grain)	T5	300 °C, 40 MPa	5 × 10⁻⁸	5.0	\		Dislocation climb
Al-7Cu [44]	6.4Cu-0.19Mn-0.13Zr (gravity cast, large grain)	T5	300 °C, 40 MPa	7 × 10⁻⁹	4.2	\	\	Dislocation climb
RR350 [44]	4.8Cu-0.19Mn-0.17Zr-1.2Ni-0.26Co-0.21Ti (gravity cast)	T5	300 °C, 60 MPa	∼1.5 × 10⁻⁸	7.2	\	\	Dislocation climb
Al-Cu [55]	6.0Cu-0.15Mn-0.25Ti-0.13V-0.13Zr (gravity cast)	T6	200 °C, 80 MPa	2.18 × 10⁻⁵	18.1	166	\	Dislocation climb	Pr reduces θ′ size, increases density and thermal stability
Al-Cu [55]	+0.3Pr (gravity cast)	T6	200 °C, 80 MPa	5.17 × 10⁻⁶	19.6	216	\	Dislocation climb	Pr reduces θ′ size, increases density and thermal stability
Al-Cu [56]	5.5Cu-0.45Mn-0.3Ti-0.2V-0.2Cd-0.15Zr (gravity cast)	T6	200 °C, 80 MPa	2.18 × 10⁻⁵	18.1	166	45	Dislocation climb	Rare earth compounds pin grain boundaries and stabilize θ′ precipitate
	+0.3Pr (gravity cast)	T6	200 °C, 80 MPa	5.17 × 10⁻⁶	19.6	216	51
	+0.3La (gravity cast)	T6	200 °C, 80 MPa	4.47 × 10⁻⁶	20.3	260	55
	+0.2La and 0.1Pr (gravity cast)	T6	200 °C, 80 MPa	4.11 × 10⁻⁶	21.7	266	\

Alloy code	Composition (wt%)	Processing condition	Creep conditions	Creep rate (s⁻¹)	n	Q (kJ/mol)	σth (MPa)	Creep mechanism	Strengthening mechanism
Al-Si-Mg [36]	Si: 6.5-7.5, Mg: 0.45-0.75	Pressure: 35 kPa	300 °C, 90 MPa	1.833 × 10⁻⁵	\	\		\	Increased differential pressure refines eutectic Si, improves distribution uniformity, hinders grain boundary sliding and crack coalescence
Al-Si-Mg [36]	Si: 6.5-7.5, Mg: 0.45-0.75	Pressure: 185 kPa	300 °C, 90 MPa	4.444 × 10⁻⁶	\	\	\	\
Al-Si [37]	Si: 7, Na: 0.02	ECAP, 1 P	300 °C, 50 MPa	∼1 × 10⁻³	5.9	223	\	Substructure sliding creep	Eutectic structure disrupted, Si particles redistributed, fine Si precipitates uniformly in matrix
Al-Si-Mg [65]	Si: 10, Mg: 0.6	L-PBF	300 °C, 45 MPa	∼8 × 10⁻⁶	10	256	18	Power-law dislocation creep	Load transfer, submicron-‍spaced lamellae effectively hinder dislocations
Al-Si-Cu-Mg [70]	Si: 6.65, Mg: 0.66, Cu: 0.56	T7	300 °C, 24 MPa	∼1.1 × 10⁻⁸	8.7	\	11	Dislocation mechanism	Mg and Cu alloying form Q phase, the only stable phase at 300 °C
Al-Si-Cu-Mg + Mo, Mn [71]	Si: 6.49, Mg: 0.31, Cu: 0.53, Mo: 0.29	T7	300 °C, ∼25 MPa	∼6 × 10⁻⁹	4.4	\	20	Dislocation mechanism	Mo alloying forms α-Al(Fe, Mo)Si dispersoids in matrix
Al-Si-Cu-Mg + Mo, Mn [71]	Si: 6.66, Mg: 0.36, Cu: 0.56, Mo: 0.34, Mn: 0.18	T7	300 °C, ∼25.5 MPa	∼2 × 10⁻⁹	4.4	\	23	Dislocation mechanism	Mn replaces some Fe, increasing dispersoids count and reducing size
Al-Si-Mg + Zr [72]	Si: 6.85, Mg: 0.32	T6	300 °C, 25 MPa	2.99 × 10⁻³	\	\	\	\	Eutectic Si modification, forming thermally stable coherent/semi-coherent nano dispersoids
Al-Si-Mg + Zr [72]	Si: 6.85, Mg: 0.32, Zr: 0.16	T6	300 °C, 25 MPa	1.35 × 10⁻³	\	\	\	\
Al-Si-Mg + Y, Ce [76]	Si: 7, Mg: 1, Y: 0.3	Vacuum differential pressure casting	200 °C, 90 MPa	3.027 × 10⁻⁷	3.52	\	\	Dislocation viscous glide	Rare earth elements promote eutectic Si fiberization and adsorb on Mg₂Si surfaces to inhibit coarsening
Al-Si-Mg + Y, Ce [76]	Si: 7, Mg: 1, Ce: 0.3	Vacuum differential pressure casting	200 °C, 90 MPa	4.97 × 10⁻⁷	3.88	\	\	Dislocation viscous glide