Effect of annealing on microstructure and mechanical properties of AlCrFe2Ni2 medium entropy alloy fabricated by laser powder bed fusion additive manufacturing

In this paper, a Co-free AlCrFe2Ni2 medium entropy alloy (MEA) has been fabricated by laser powder bed fusion additive manufacturing and treated by subsequent annealing at various temperatures ranging from 750 °C to 1050 °C to achieve good strength-ductility synergy. The effect of annealing on the m...

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Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2022-04, Vol.839, p.142868, Article 142868
Main Authors: Han, Tianyi, Liu, Yong, Yang, Danni, Qu, Nan, Liao, Mingqing, Lai, Zhonghong, Jiang, Meng, Zhu, Jingchuan
Format: Article
Language:English
Subjects:
Additive manufacturing
Alloys
Annealing
Body centered cubic lattice
Chromium
Compressive strength
Ductility
Entropy
Face centered cubic lattice
Heat treatment
Heterogeneity
Heterogeneous microstructure
Heterogeneous structure
Iron
Manufacturing
Mechanical properties
Medium entropy alloy
Medium entropy alloys
Microstructure
Nickel
Phase distribution
Powder beds
Strain hardening
Strengthening mechanism
Yield strength
Yield stress
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Summary:In this paper, a Co-free AlCrFe2Ni2 medium entropy alloy (MEA) has been fabricated by laser powder bed fusion additive manufacturing and treated by subsequent annealing at various temperatures ranging from 750 °C to 1050 °C to achieve good strength-ductility synergy. The effect of annealing on the microstructure, phase distribution and mechanical properties was systematically investigated by characterizing the as-built and the subsequently annealed alloys. The as-built MEA showed a microstructure of homogeneously distributed ordered B2 single-phase, and exhibited a great compressive yield strength of over 1850 MPa but relatively insufficient ductility of 13.8%. After annealing, the microstructure transformed to a heterogeneous structure with Ni–Al rich ordered B2 and Fe–Ni–Cr rich FCC phases, as well as a few Fe–Cr rich BCC phase. With the increase of annealing temperature to 1050 °C, the ductility of the annealed MEAs significantly improved while the compressive yield strength decreased from 1185.85 MPa (as-built) to 614.93 MPa. Despite the certainly compromised yield strength, a good strength-ductility synergy and superior strain hardening capacity of the additively manufactured MEA were achieved via subsequent heat treatment. Furthermore, the underlying mechanisms of the decreased yield strength under high annealing temperature and the superior strain hardening capacity of the annealed alloy were analyzed. The findings of this work show the feasibility of achieving the required strength-ductility synergy of additively manufactured HEAs/MEAs by tailoring microstructural heterogeneity using subsequent heat treatment. •The AlCrFe2Ni2 MEAs are prepared by LPBF and subsequent annealing.•After annealing, the as-built AlCrFe2Ni2 with single phase transforms to a heterogeneous structure with B2 and FCC phases.•A good strength-ductility synergy and strain hardening capacity of the as-built MEAs were achieved via annealing.•Dislocation and Orowan are dominant strengthening mechanisms in the annealed AlCrFe2Ni2 MEAs.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2022.142868