Hot deformation behaviour and microstructure control in AlCrCuNiFeCo high entropy alloy

• Published in: Intermetallics Vol. 55; pp. 145 - 153
• Main Authors: Nayan, Niraj, Singh, Gaurav, Murty, S.V.S.N., Jha, Abhay K., Pant, Bhanu, George, Koshy M., Ramamurty, Upadrasta
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.12.2014
• Subjects: A. High–entropy alloys; B. Constitutive equation; B. Deformation map; C. Thermomechanical processing; D. Microstructure; Deformation; Deformation mechanisms; Entropy; Hot working; Instability; Mathematical models; Microstructure; Strain rate; D. Microstructure; A. High–entropy alloys; B. Deformation map; B. Constitutive equation; C. Thermomechanical processing
• ISSN: 0966-9795; 1879-0216
• DOI: 10.1016/j.intermet.2014.07.019

An AlCrCuNiFeCo high entropy alloy (HEA), which has simple face centered cubic (FCC) and body centered cubic (BCC) solid solution phases as the microstructural constituents, was processed and its high temperature deformation behaviour was examined as a function of temperature (700–1030 °C) and strain rate (10−3–10−1 s−1), so as to identify the optimum thermo-mechanical processing (TMP) conditions for hot working of this alloy. For this purpose, power dissipation efficiency and deformation instability maps utilizing that the dynamic materials model pioneered by Prasad and co-workers have been generated and examined. Various deformation mechanisms, which operate in different temperature–strain rate regimes, were identified with the aid of the maps and complementary microstructural analysis of the deformed specimens. Results indicate two distinct deformation domains within the range of experimental conditions examined, with the combination of 1000 °C/10−3 s−1 and 1030 °C/10−2 s−1 being the optimum for hot working. Flow instabilities associated with adiabatic shear banding, or localized plastic flow, and or cracking were found for 700–730 °C/10−3–10−1 s−1 and 750–860 °C/10−1.4–10−1 s−1 combinations. A constitutive equation that describes the flow stress of AlCrCuNiFeCo alloy as a function of strain rate and deformation temperature was also determined. •AlCrCuNiFeCo high entropy alloy was processed by vacuum induction melting (VIM) route.•Power dissipation efficiency and instability maps generated.•Various deformation mechanisms in different temperature–strain rate regimes identified.•A constitutive equation correlating flow stress, strain rate, and temperature established.