Journal article
Probing the mechanisms of morphological evolution and phase selection of intermetallic compounds for impurity-tolerant processing of recycled Al alloys
- Abstract:
- Fe-rich intermetallic compounds (IMCs) are a persistent challenge in the recirculation of secondary aluminium alloys. Despite significant research effort, largely via post-solidification studies, the mechanisms governing IMC phase selection in higher-Fe ( > 1 wt.%), recycled Al alloys and how they can be controlled to facilitate more benign IMC species and/or morphologies remain poorly understood. This creates barriers to compositional and process design for more Fe-tolerant alloys. In this paper, we present a systematic real-time investigation of IMC formation, phase selection and morphological evolution in recycled 3xx series Al alloys with elevated Fe concentrations (up to 2.5 wt%), using in situ synchrotron X-ray radiography. Coupled with thermodynamic simulations, we develop a method to reliably estimate the formation temperatures of primary α -AlFeSi and β -AlFeSi IMCs, and show direct insights into their formation sequence and kinetics. Contrary to widely held assumptions based on low Fe-containing ( < 0.6 wt%) primary alloys, we show that in recycled alloys containing higher Fe concentrations, increased cooling rate significantly promotes the formation of the more anisotropic β -AlFeSi (over the more compact α -AlFeSi), which however can be fully suppressed at slow cooling. We propose how a solute-suppression mechanism kinetically controls the α / β IMC phase evolution. Further, we reveal and quantify a faceted-to-non-faceted morphological transition of α -AlFeSi from a faceted polyhedral to non-faceted near-equiaxed dendritic morphology. This transition is governed by an interplay between solidification velocity and liquid undercooling at the local IMC/liquid interfaces. This study provides insights into how solidification conditions may be leveraged to improve microstructural control in high Fe-containing recycled alloys.
- Publication status:
- Published
- Peer review status:
- Peer reviewed
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(Preview, Accepted manuscript, pdf, 13.4MB, Terms of use)
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(Preview, Supplementary materials, pdf, 4.3MB, Terms of use)
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- Publisher copy:
- 10.1016/j.actamat.2025.121591
Authors
+ Engineering and Physical Sciences Research Council
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- Funder identifier:
- https://ror.org/0439y7842
- Grant:
- EP/W024829/1
- EP/X03884X/1
- Publisher:
- Elsevier
- Journal:
- Acta Materialia More from this journal
- Volume:
- 301
- Article number:
- 121591
- Publication date:
- 2025-10-03
- Acceptance date:
- 2025-09-26
- DOI:
- EISSN:
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1873-2453
- ISSN:
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1359-6454
- Language:
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English
- Keywords:
- Pubs id:
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2301265
- UUID:
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uuid_98905b43-3570-4af4-af1e-3fc0357632b2
- Local pid:
-
pubs:2301265
- Deposit date:
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2025-11-18
- ARK identifier:
Terms of use
- Copyright holder:
- Acta Materialia Inc
- Copyright date:
- 2025
- Rights statement:
- © 2025 Acta Materialia Inc. Published by Elsevier Inc. All rights are reserved, including those for text and data mining, AI training, and similar technologies.
- Notes:
- The author accepted manuscript (AAM) of this paper has been made available under the University of Oxford's Open Access Publications Policy, and a CC BY public copyright licence has been applied.
- Licence:
- CC Attribution (CC BY)
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