Transformation of the Metastable Al6Fe Intermetallic Phase during Homogenization of a Binary Al-Fe Alloy

Arbeiter, Jože; Vončina, Maja; Batič, Barbara Šetina; Medved, Jožef

doi:10.3390/ma14237208

Cited by 7 publications

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“…This value well corresponds to the Fe content of the most stable Al‐Fe phase, Al 3 Fe. [ 46 ] Meanwhile, the Al‐rich region showed 13 at.% Fe content ratio, which approximately corresponds to the composition of a major metastable Al‐Fe phase, Al 6 Fe. [ 46 ] Although the existence of the Al‐rich region is a clear difference between the small and large IMPs, this does not explain the difference in their corrosion behaviors.…”

Section: Resultsmentioning

confidence: 99%

“…[ 46 ] Meanwhile, the Al‐rich region showed 13 at.% Fe content ratio, which approximately corresponds to the composition of a major metastable Al‐Fe phase, Al 6 Fe. [ 46 ] Although the existence of the Al‐rich region is a clear difference between the small and large IMPs, this does not explain the difference in their corrosion behaviors. Thus, the compositional difference is unlikely to induce the different corrosion behaviors.…”

Section: Resultsmentioning

confidence: 99%

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Size‐Dependent Corrosion of Al‐Fe Intermetallic Particles at Al‐Mg Alloy Surfaces Investigated by In‐Liquid Nanoscale Potential Measurement Technique

Hirata

Okamoto

Kitagawa

et al. 2023

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Corrosion of Al alloy often starts from the nanoscale corrosion around the surface‐exposed Al‐Fe intermetallic particles (IMPs) and leads to a serious damage limiting its application range in the automobile industry. To solve this issue, understanding of the nanoscale corrosion mechanism around the IMP is essential, yet it is impeded by the difficulties in directly visualizing nanoscale distribution of reaction activity. Here, this difficulty is overcomed by open‐loop electric potential microscopy (OL‐EPM) and investigate nanoscale corrosion behavior around the IMPs in H2SO4 solution. The OL‐EPM results reveal that the corrosion around a small IMP settles down in a short time (<30 min) after transient dissolution of the IMP surface while that around a large IMP lasts for a long time especially at its edges and results in a severe damage of the IMP and matrix. This result suggests that an Al alloy with many small IMPs gives a better corrosion resistance than that with few large IMPs if the total Fe content is the same. This difference is confirmed by corrosion weight loss test using Al alloys with different IMP sizes. This finding should give an important guideline to improve the corrosion resistance of Al alloy.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%