A. Wilm, Physikalisch-metallurgische Untersuchungen über magnesiumhaltige Aluminiumlegierungen, vol.8, pp.225-227, 1911.

W. S. Miller, L. Zhuang, J. Bottema, A. J. Wittebrood, P. De-s-met et al., Recent development in aluminium alloys for the automotive industry, Mater. Sci. Eng. A, vol.280, issue.14, pp.63305-63312, 2000.

T. Dursun and C. Soutis, Recent developments in advanced aircraft aluminium alloys, Mater. Design, vol.56, pp.862-871, 2014.

E. O. Hall, The deformation and ageing of mild steel: III Discussion of results, Proc. Phys. Soc. B, vol.64, pp.747-753, 1951.

N. J. Petch, The Cleavage Strength of Polycrystals, J. Iron Steel Inst, vol.174, pp.25-28, 1953.

R. Z. Valiev, Y. Estrin, Z. Horita, T. G. Langdon, M. J. Zehetbauer et al., Producing bulk ultrafine-grained materials by severe plastic deformation, JOM, vol.58, pp.33-39, 2006.

V. M. Segal, V. I. Reznikov, A. E. Drobyshevskiy, and V. I. Kopylov, Plastic Working of Metals by Simple Shear, Russian Metall, vol.1, pp.99-105, 1981.

P. W. Bridgman, Effects of High Shearing Stress Combined with High Hydrostatic Pressure, Phys. Rev, vol.48, pp.825-847, 1935.

Y. Saito, H. Utsunomiya, N. Tsuji, and T. Sakai, Novel ultra-high straining 20 process for bulk materials-development of the accumulative roll-bonding (ARB) process, Acta Mater, vol.47, pp.365-371, 1999.

O. R. Valiakhmetov, R. M. Galeyev, and G. A. Salishchev, Mechanical properties of the titanium alloy VT8 with submicrocrystalline structure, Fiz. Metal. Metalloved, vol.10, pp.204-206, 1990.

T. Fujioka and Z. Horita, Development of High-Pressure Sliding Process for Microstructural Refinement of Rectangular Metallic Sheets, Mater. Trans, vol.50, pp.930-933, 2009.

S. D. Terhune, D. L. Swisher, K. Oishi, Z. Horita, T. G. Langdon et al., An investigation of microstructure and grain-boundary evolution during ECA pressing of pure aluminum, Metall. Mater. Trans. A, vol.33, pp.2173-2184, 2002.

Y. Ito and Z. Horita, Microstructural evolution in pure aluminum processed by high-pressure torsion, Mater. Sci. Eng. A, vol.503, pp.32-36, 2009.

N. Tsuji, Y. Ito, Y. Saito, and Y. Minamino, Strength and ductility of ultrafine grained aluminum and iron produced by ARB and annealing, Scr. Mater, vol.47, pp.893-899, 2002.

P. V. Liddicoat, X. Z. Liao, Y. Zhao, Y. Zhu, M. Y. Murashkin et al.,

R. Z. Lavernia, S. P. Valiev, and . Ringer, Nanostructural hierarchy increases the strength of aluminium alloys, vol.1, p.63, 2010.

R. Z. Valiev, N. A. Enikeev, M. Yu, V. U. Murashkin, X. Kazykhanov et al., On the origin of the extremely high strength of ultrafine-grained Al alloys produced by severe plastic deformation, Scr. Mater, vol.63, pp.949-952, 2010.
URL : https://hal.archives-ouvertes.fr/hal-00526517

I. F. Mohamed, Y. Yonenaga, S. Lee, K. Edalati, and Z. Horita, Age hardening and thermal stability of Al-Cu alloy processed by high-pressure torsion

. Sci and . Eng, A, vol.627, pp.111-118, 2015.

I. F. Mohamed, T. Masuda, S. Lee, K. Edalati, Z. Horita et al., Strengthening of A2024 alloy by high-pressure torsion and subsequent aging, Mater. Sci. Eng. A, vol.704, pp.112-118, 2017.

Y. Tang, W. Goto, S. Hirosawa, Z. Horita, S. Lee et al., Concurrent strengthening of ultrafine-grained age-hardenable Al-Mg alloy by means of high-pressure torsion and spinodal decomposition, Acta Mater, vol.131, pp.57-64, 2017.

W. J. Kim, C. S. Chung, D. S. Ma, S. I. Hong, and H. K. Kim, Optimization of strength and ductility of 2024 Al by equal channel angular pressing (ECAP) and post-ECAP aging, Scr. Mater, vol.49, pp.333-338, 2003.

S. Lee, Z. Horita, S. Hirosawa, and K. Matsuda, Age-hardening of an Al-Li-Cu-Mg alloy (2091) processed by high-pressure torsion, Mater. Sci. Eng. A, vol.546, pp.82-89, 2012.

T. Masuda, Y. Takizawa, M. Yumoto, Y. Otagiri, and Z. Horita, Extra Strengthening and Superplasticity of Ultra¬ne-Grained A2024 Alloy Produced by High-Pressure Sliding, vol.58, pp.1647-1655, 2017.

A. Deschamps, F. De-geuser, Z. Horita, S. Lee, and G. Renou, Precipitation kinetics in a severely plastically deformed 7075 aluminium alloy, Acta Mater, vol.66, pp.105-117, 2014.
URL : https://hal.archives-ouvertes.fr/hal-00963756

Y. H. Zhao, X. Z. Liao, Z. Jin, R. Z. Valiev, and Y. T. Zhu, Microstructures and mechanical properties of ultrafine grained 7075 Al alloy processed by ECAP and their evolutions during annealing, Acta Mater, vol.52, pp.4589-4599, 2004.

K. S. Ghosh, N. Gao, and M. J. Starink, , p.22

, Mater. Sci. Eng. A, vol.552, pp.164-171, 2012.

S. P. Ringer, K. Hono, I. J. Polmear, and T. Sakurai, Precipitation processes during the early stages of ageing in A1-Cu-Mg alloys, vol.94, pp.253-260, 1996.

Y. Nasedkina, X. Sauvage, E. V. Bobruk, M. Y. Murashkin, R. Z. Valiev et al., Enikeev: Mechanisms of precipitation induced by large strains in the Al -Cu system, J. Alloys Comp, vol.710, pp.736-747, 2017.

W. Xu, X. C. Liu, X. Y. Li, and K. Lu, Deformation induced grain boundary segregation in nanolaminated Al-Cu alloy, Acta Materialia, vol.182, pp.207-214, 2020.

X. Sauvage, A. Duchaussoy, and G. Zaher, Strain induced segregations in severely deformed materials, Mat. Trans, vol.60, issue.7, pp.1151-1158, 2019.
URL : https://hal.archives-ouvertes.fr/hal-02307613

G. Sha, R. K. Marceau, X. Gao, B. C. Muddle, and S. P. Ringer, Nanostructure of aluminium alloy 2024: Segregation, clustering and precipitation processes, Acta Mater, vol.59, pp.1659-1670, 2011.

A. Alhamidi and Z. Horita, Grain refinement and high strain rate superplasticity in alumunium 2024 alloy processed by high-pressure torsion, Mater. Sci. Eng. A, vol.622, pp.139-145, 2015.

Y. Chen, N. Gao, G. Sha, S. P. Ringer, and M. J. Starink, Strengthening of an Al-Cu-Mg alloy processed by high-pressure torsion due to clusters, defects and defect-cluster complexes, Mater. Sci. Eng. A, vol.627, pp.10-20, 2015.

Y. Chen, N. Gao, G. Sha, S. P. Ringer, and M. J. Starink, Microstructural evolution, strengthening and thermal stability of an ultrafine -grained Al-Cu-Mg alloy, Acta Mater, vol.109, pp.202-212, 2016.

S. V. Dobatkin, E. N. Bastarache, G. Sakai, T. Fujita, Z. Horita et al., Grain refinement and superplastic flow in an aluminum alloy processed by high-pressure torsion, Mater. Sci. Eng. A, vol.408, pp.141-146, 2005.

G. K. Williamson and W. H. Hall, X-ray line broadening from filed aluminium and wolfram, Acta Metall, vol.1, issue.53, pp.90006-90012, 1953.

G. K. Williamson and R. E. , Smallman: III. Dislocation densities in some annealed and cold-worked metals from measurements on the X-ray debyescherrer spectrum, Philos. Mag, vol.8, pp.24-46, 1956.

B. E. Warren and J. Biscoe, The Structure of Silica Glass by X-Ray Diffraction Studies, J. Am. Ceram. Soc, vol.21, pp.49-54, 1938.

A. Biswas, D. J. Siegel, C. Wolverton, and D. N. Seidman, Precipitates in Al-Cu alloys revisited: Atom-probe tomographic experiments and first-principles calculations of compositional evolution and interfacial segregation, Acta Mater, vol.59, pp.6187-6204, 2011.

I. Sabirov, M. Y. Murashkin, and R. Z. Valiev, Nanostructured aluminium 24 alloys produced by severe plastic deformation: New horizons in development, Mater. Sci. Eng. A, vol.560, pp.1-24, 2013.

N. Hansen, The effect of grain size and strain on the tensile flow stress of aluminium at room temperature, Acta Metall, vol.25, pp.90171-90178, 1977.

R. L. Fleischer, Substitutional solution hardening, Acta Metall, vol.11, pp.203-209, 1963.

R. Labusch, Statistical theories of solid solution hardening, Acta Metall, vol.20, pp.917-927, 1972.

J. E. Bailey and P. B. Hirsch, The dislocation distribution, flow stress, and stored energy in cold-worked polycrystalline silver, Philos. Mag, vol.5, pp.485-497, 1960.

N. Hansen and X. Huang, Microstructure and flow stress of polycrystals and single crystals, Acta Mater, vol.46, pp.1827-1836, 1998.

G. I. Taylor, Plastic Strain in Metals, J. Inst. Met, vol.62, pp.307-324, 1938.

G. Y. Chin and W. L. Mammel, Computer Solutions of the Taylor Analysis for Axisymmetric Flow, Trans. of the Met. Soc. of AIME, vol.239, pp.1400-1405, 1967.

B. Clausen, Characterisation of Polycrystal Deformation by Numerical Modelling and Neutron Diffraction Experiments, 1997.

T. Shanmugasundaram, M. Heilmaier, B. S. Murty, and V. S. Sarma, On the Hall-Petch relationship in a nanostructured Al-Cu alloy, Mater. Sci. Eng. A, vol.527, pp.7821-7825, 2010.

N. Q. Vo, J. Schäfer, R. S. Averback, K. Albe, Y. Ashkenazy et al., Reaching theoretical strengths in nanocrystalline Cu by grain boundary doping, vol.65, pp.660-663, 2011.

D. Zhao, O. M. Løvvik, K. Marthinsen, and Y. Li, Segregation of Mg, Cu and their effects on the strength of Al ?5 (210)[001] symmetrical tilt grain boundary, Acta Mater, vol.145, pp.235-246, 2018.

Y. M. Wang, T. Voisin, J. T. Mckeown, J. Ye, N. P. Calta et al.,

W. Zhang, T. T. Chen, R. T. Roehling, M. K. Ott, P. J. Santala et al.,

A. V. Mattews, T. Hamza, and . Zhu, Additively manufactured hierarchical stainless steels with high strength and ductility, Nat. Mater, vol.17, pp.63-71, 2018.

M. Zhao, F. Yin, T. Hanamura, K. Nagai, and A. Atrens, Relationship between yield strength and grain size for a bimodal structural ultrafine -grained ferrite/cementite steel, Scr. Mater, vol.57, pp.857-860, 2007.

X. Huang, N. Hansen, and N. Tsuji, Hardening by Annealing and Softening by Deformation in Nanostructured Metals, Science, pp.249-251, 2006.