Unraveling the potential of Cu addition and cluster hardening in Al-Mg-Si alloys

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Unraveling the potential of Cu addition and cluster hardening in Al-Mg-Si alloys. / Aster, Philip; Dumitraschkewitz, Phillip; Uggowitzer, Peter et al.
In: Materialia, Vol. 36.2024, No. August, 102188, 24.07.2024.

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Aster P, Dumitraschkewitz P, Uggowitzer P, Tunes MA, Schmid F, Stemper L et al. Unraveling the potential of Cu addition and cluster hardening in Al-Mg-Si alloys. Materialia. 2024 Jul 24;36.2024(August):102188. doi: 10.1016/j.mtla.2024.102188

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@article{5599a84d73a54c358b77174c83547abf,
title = "Unraveling the potential of Cu addition and cluster hardening in Al-Mg-Si alloys",
abstract = "With the aim of further exploiting the trade-off between formability and strength in Al alloys, this study addresses the influence of Cu in Al-Mg-Si alloys that achieve simultaneously high strength and high ductility via cluster hardening. The study carefully examines the mechanical properties and strain hardening behavior of various Mg/Si ratios with and without Cu and compares the effects of pre-aging and atypical long-term low-temperature aging treatments at 100°C to conventional heat treatments. Interestingly, in all cases adding Cu improved ductility. In the extremal case cluster hardening plus the addition of Cu quadruples elongation, while keeping yield strength similar to the classical T6 state. The results of the study are discussed with a focus on the dense distribution of clusters and partial hardening phases based on atom probe tomography data. Most importantly, the cluster-hardened alloys exhibit pronounced strain-hardening properties, which we evaluate using a Kocks-Mecking approach in combination with a microstructural analysis in the pre-aging and long-term aging condition. The key finding of the study involves the role of Cu in refining clusters/precipitates, where it causes a substantial increase in number density and volume fraction. This refinement, in combination with strain-induced clustering, contributes significantly to improving the alloys{\textquoteright} overall mechanical performance and underlines the central role of Cu in tailoring microstructural features, especially in alloys primarily strengthened by clusters.",
keywords = "Aluminum alloys, APT, Cluster hardening, Dynamic recovery, Mechanical testing, Microstructure evolution",
author = "Philip Aster and Phillip Dumitraschkewitz and Peter Uggowitzer and Tunes, {Matheus Araujo} and Florian Schmid and Lukas Stemper and Stefan Pogatscher",
note = "Publisher Copyright: {\textcopyright} 2024 The Author(s)",
year = "2024",
month = jul,
day = "24",
doi = "10.1016/j.mtla.2024.102188",
language = "English",
volume = "36.2024",
journal = "Materialia",
issn = "2589-1529",
publisher = "Elsevier",
number = "August",

}

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TY - JOUR

T1 - Unraveling the potential of Cu addition and cluster hardening in Al-Mg-Si alloys

AU - Aster, Philip

AU - Dumitraschkewitz, Phillip

AU - Uggowitzer, Peter

AU - Tunes, Matheus Araujo

AU - Schmid, Florian

AU - Stemper, Lukas

AU - Pogatscher, Stefan

N1 - Publisher Copyright: © 2024 The Author(s)

PY - 2024/7/24

Y1 - 2024/7/24

N2 - With the aim of further exploiting the trade-off between formability and strength in Al alloys, this study addresses the influence of Cu in Al-Mg-Si alloys that achieve simultaneously high strength and high ductility via cluster hardening. The study carefully examines the mechanical properties and strain hardening behavior of various Mg/Si ratios with and without Cu and compares the effects of pre-aging and atypical long-term low-temperature aging treatments at 100°C to conventional heat treatments. Interestingly, in all cases adding Cu improved ductility. In the extremal case cluster hardening plus the addition of Cu quadruples elongation, while keeping yield strength similar to the classical T6 state. The results of the study are discussed with a focus on the dense distribution of clusters and partial hardening phases based on atom probe tomography data. Most importantly, the cluster-hardened alloys exhibit pronounced strain-hardening properties, which we evaluate using a Kocks-Mecking approach in combination with a microstructural analysis in the pre-aging and long-term aging condition. The key finding of the study involves the role of Cu in refining clusters/precipitates, where it causes a substantial increase in number density and volume fraction. This refinement, in combination with strain-induced clustering, contributes significantly to improving the alloys’ overall mechanical performance and underlines the central role of Cu in tailoring microstructural features, especially in alloys primarily strengthened by clusters.

AB - With the aim of further exploiting the trade-off between formability and strength in Al alloys, this study addresses the influence of Cu in Al-Mg-Si alloys that achieve simultaneously high strength and high ductility via cluster hardening. The study carefully examines the mechanical properties and strain hardening behavior of various Mg/Si ratios with and without Cu and compares the effects of pre-aging and atypical long-term low-temperature aging treatments at 100°C to conventional heat treatments. Interestingly, in all cases adding Cu improved ductility. In the extremal case cluster hardening plus the addition of Cu quadruples elongation, while keeping yield strength similar to the classical T6 state. The results of the study are discussed with a focus on the dense distribution of clusters and partial hardening phases based on atom probe tomography data. Most importantly, the cluster-hardened alloys exhibit pronounced strain-hardening properties, which we evaluate using a Kocks-Mecking approach in combination with a microstructural analysis in the pre-aging and long-term aging condition. The key finding of the study involves the role of Cu in refining clusters/precipitates, where it causes a substantial increase in number density and volume fraction. This refinement, in combination with strain-induced clustering, contributes significantly to improving the alloys’ overall mechanical performance and underlines the central role of Cu in tailoring microstructural features, especially in alloys primarily strengthened by clusters.

KW - Aluminum alloys

KW - APT

KW - Cluster hardening

KW - Dynamic recovery

KW - Mechanical testing

KW - Microstructure evolution

UR - http://www.scopus.com/inward/record.url?scp=85200117060&partnerID=8YFLogxK

U2 - 10.1016/j.mtla.2024.102188

DO - 10.1016/j.mtla.2024.102188

M3 - Article

AN - SCOPUS:85200117060

VL - 36.2024

JO - Materialia

JF - Materialia

SN - 2589-1529

IS - August

M1 - 102188

ER -