Severe plastic deformation driven nanostructure and phase evolution in a Al^sub 0.5^CoCrFeMnNi dual phase high entropy alloy

Severe plastic deformation driven nanostructure and phase evolution in a Al^sub 0.5^CoCrFeMnNi dual phase high entropy alloy

The effect of severe plastic deformation on microstructure and phase evolution was investigated in a dual phase Al0.5CoCrFeMnNi high entropy alloy (HEA). For this purpose, the as-cast HEA was subjected to initial thermo- mechanical processing by warm-rolling and annealing. The annealed dual phase al...

Full description

Saved in:
Bibliographic Details
Published in:Intermetallics Vol. 91; p. 150
Main Authors: Reddy, TS, Wani, IS, Bhattacharjee, T, Reddy, SR, Saha, R, Bhattacharjee, PP
Format: Journal Article
Language:English
Published: Barking Elsevier BV 01-12-2017
Subjects:
Aluminum
Annealing
Deformation effects
Entropy
Evolution
Hardness
High entropy alloys
Homogeneity
Microstructure
Nanostructure
Nickel
Plastic deformation
Recrystallization
Studies
Warm rolling
Warm working
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The effect of severe plastic deformation on microstructure and phase evolution was investigated in a dual phase Al0.5CoCrFeMnNi high entropy alloy (HEA). For this purpose, the as-cast HEA was subjected to initial thermo- mechanical processing by warm-rolling and annealing. The annealed dual phase alloy showed FCC and B2 phases. The B2 phase was enriched with Ni and Al, while the converse held good for the FCC phase. These annealed HEA specimens were severely deformed by high pressure torsion (HPT) up to five complete rotations (R). The severely deformed HEA revealed nanostructured FCC grains containing nano-twinned regions and coarser B2 phase. The nanostructure formation in the softer FCC phase was attributed to greater strain partitioning and propensity for the formation of nano-twins. Although with increasing rotations, the hardness dif- ference between the edge and centre region was reduced, the SR HPT processed specimens showed in- homogeneity featured by intermittent hardness spikes. Upon annealing, recrystallized dual phase microstructure was confirmed in the 5R UPT processed specimen. Microstructural differences between centre and edge regions were revealed by way of large B2 clusters (5 μm-10 μm) at the centre region. Remarkably, annealing resulted in the formation of a (Fe,Cr) rich a-phase. The formation of a-phase resulted in much greater hardness in- homogeneity in the annealed material as compared to the 5R HPT processed material.
ISSN:0966-9795
1879-0216