TY - JOUR
T1 - Strengthening of nanocrystalline Al using grain boundary solute additions
T2 - Effects of thermal annealing and ion irradiation
AU - Kim, Sung Eun
AU - Verma, Nisha
AU - Özerinç, Sezer
AU - Jana, Soumyajit
AU - Das, Sourav
AU - Bellon, P.
AU - Averback, R. S.
N1 - Publisher Copyright:
© 2022 Acta Materialia Inc.
PY - 2022/12
Y1 - 2022/12
N2 - Strengthening of nanocrystalline Al by grain boundary solute additions was investigated for a series of dilute aluminum alloys, Al-Sc, Al-Sb, Al-Cr, and Al-W with grain sizes in the range of 50–200 nm. Thermal annealing of the alloys at low temperatures led to alloy softening, but with negligible change in the grain size. The reduction in strength can be attributed to the loss of solute in the grain boundaries arising from grain boundary diffusion and precipitation. Annealing at higher temperatures led to grain growth, but with little additional loss of strength, a result of precipitation hardening. The Al-Sc and Al-Sb alloys were additionally subjected to ion irradiation at various temperatures. These studies revealed that annealed samples regained their hardness due to solute redistribution by ion beam mixing. Alloy strength was independent of grain size between 50 and 150 nms. Irradiation-induced segregation of Sb to grain boundaries in Al-Sb further enhanced strengthening.
AB - Strengthening of nanocrystalline Al by grain boundary solute additions was investigated for a series of dilute aluminum alloys, Al-Sc, Al-Sb, Al-Cr, and Al-W with grain sizes in the range of 50–200 nm. Thermal annealing of the alloys at low temperatures led to alloy softening, but with negligible change in the grain size. The reduction in strength can be attributed to the loss of solute in the grain boundaries arising from grain boundary diffusion and precipitation. Annealing at higher temperatures led to grain growth, but with little additional loss of strength, a result of precipitation hardening. The Al-Sc and Al-Sb alloys were additionally subjected to ion irradiation at various temperatures. These studies revealed that annealed samples regained their hardness due to solute redistribution by ion beam mixing. Alloy strength was independent of grain size between 50 and 150 nms. Irradiation-induced segregation of Sb to grain boundaries in Al-Sb further enhanced strengthening.
KW - Grain boundary strengthening
KW - atom probe tomography
KW - dilute Al alloys
KW - precipitate hardening
KW - radiation induced mixing
KW - radiation induced segregation
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U2 - 10.1016/j.mtla.2022.101564
DO - 10.1016/j.mtla.2022.101564
M3 - Article
AN - SCOPUS:85144495635
SN - 2589-1529
VL - 26
JO - Materialia
JF - Materialia
M1 - 101564
ER -