2.3 GPa cryogenic strength through thermal-induced and deformation-induced body-centered cubic martensite in a novel ferrous medium entropy alloy

• Published in: Scripta materialia Vol. 204; p. 114157
• Main Authors: Kwon, Hyeonseok, Sathiyamoorthi, Praveen, Karthik, Gangaraju Manogna, Asghari-Rad, Peyman, Zargaran, Alireza, Do, Hyeon-Seok, Lee, Byeong-Joo, Kato, Hidemi, Kim, Hyoung Seop
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.11.2021
• Subjects: Dislocation structure; Maraging medium-entropy alloys; Martensitic phase transformation; Plastic deformation; Work hardening; Dislocation structure; Work hardening; Plastic deformation; Martensitic phase transformation; Maraging medium-entropy alloys
• ISSN: 1359-6462; 1872-8456
• DOI: 10.1016/j.scriptamat.2021.114157

A novel non-equiatomic FeCoNiAlTiMo ferrous medium-entropy alloy (MEA) with ultra-high tensile strengths at 298 and 77 K is presented in this work. By subjecting the MEA to hot rolling without further heat treatment, a quasi-dual-phase microstructure consisting of retained face-centered cubic (FCC) and thermal body-centered cubic martensite (BCC) phases with a very high density of dislocations and precipitates of Mo-rich µ phase was created. The high dislocation density significantly accelerated deformation-induced martensitic transformation from the remaining metastable FCC to BCC and successfully increased strain hardening ability. The strain hardening ability was even higher at 77 K due to decreasing FCC phase stability at lower temperatures. The increased strain hardening ability led to an excellent balance of strength and ductility, with ultimate tensile strength/uniform elongation of ~1.5 GPa/~15% at 298 K and ~2.3 GPa/~11% at 77 K. [Display omitted]