Evolution of Near-Surface Deformed Layers on AA3104 Aluminium Alloy

Kai Li; Xiao Rong Zhou; George E. Thompson; John A. Hunter; Yu Die Yuan

doi:10.4028/www.scientific.net/MSF.765.358

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Characterizing the Asymmetric/Anisotropic Deformation Response and Forming Behaviour of Wrought Magnesium and Titanium Alloys
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Manufacture of CNTs-Al Powder Precursors for Casting of CNTs-Al Matrix Composites
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Evolution of Near-Surface Deformed Layers on AA3104 Aluminium Alloy
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Influence of Groove Pressing Process on the Drawability (R Value) of Aluminium Alloy AA 5052 Sheets
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Numerical Investigation on the Hot Forming and Cold-Die Quenching of an Aluminium-Magnesium Alloy into a Complex Component
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A Review of Cooling Technologies for Flat Rolled Aluminium Products
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Formation of Bulk Nanostructured Al₃Ni from Elemental Micropowders Using High-Pressure Torsion
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HomeMaterials Science ForumMaterials Science Forum Vol. 765Evolution of Near-Surface Deformed Layers on...

Evolution of Near-Surface Deformed Layers on AA3104 Aluminium Alloy

Abstract:

The present work studied the microstructure of near-surface deformed layers and their evolution from the transfer slab to the cold rolled final gauge sheet of an AA3104 aluminium alloy. Electron microscopy of ultramicrotomed cross-sections revealed two types of near-surface deformed layers, i.e. type A and type B, both with different microstructures to the underlying bulk alloy. A typical feature of the deformed layers is the nano-sized ultrafine grains, with diameters ≤ 200 nm for the type A and ≤ 500 nm for the type B deformed layer. Electron energy loss spectroscopy (EELS) indicated that oxide particles are present along grain boundaries within the type A deformed layer, while the type B deformed layer is free of oxide particles. The type A deformed layer is mainly generated at elevated temperatures during the early stages of hot rolling. Its thickness is non-uniform across the surface, with a maximum of ~4 µm on the transfer slab, ~1 µm on the re-roll gauge sheet and ~0.8 µm on the final gauge sheet. While the surface of the hot rolled sheet is mainly covered by the type A deformed layer, the surface undergone cold rolling is alternately covered by the type A and the type B deformed layers.