Effect of carbon upon mechanical properties and deformation mechanisms of TWIP and TRIP-assisted high entropy alloys

The present work systematically investigates the effect of carbon upon a TWIP alloy Cr20Mn15Fe34Co20Ni11 and a TRIP alloy Cr20Mn24Fe30Co20Ni6. After doping 0.5 at.% C, C-TWIP and C-TRIP alloy present a single face-centred cubic phase. Both alloys have achieved simultaneous enhancement of strength an...

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Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2022-11, Vol.857, p.144126, Article 144126
Main Authors: Yuan, Kunquan, Jiang, Yan, Liu, Shichao, Xu, Songsong, Li, Xinzhong, Wu, Xiaoxiang
Format: Article
Language:English
Subjects:
Alloys
Carbon
Deformation effects
Deformation mechanisms
Doping
Ductility
Elongation
High entropy alloys
Mechanical properties
Stacking fault energy
Superalloys
Tensile deformation
Tensile strength
TRIP
TWIP
Ultimate tensile strength
Yield strength
Yield stress
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Summary:The present work systematically investigates the effect of carbon upon a TWIP alloy Cr20Mn15Fe34Co20Ni11 and a TRIP alloy Cr20Mn24Fe30Co20Ni6. After doping 0.5 at.% C, C-TWIP and C-TRIP alloy present a single face-centred cubic phase. Both alloys have achieved simultaneous enhancement of strength and ductility. The yield strength of the C-TWIP alloy increases from 130 ± 4 MPa to 235 ± 5 MPa, and the ultimate tensile strength rises from 402 ± 5 MPa to 646 ± 10 MPa, accompanied by about 40% increase in total elongation. The C-TRIP alloy also shows a simultaneous increase in strength and ductility compared to the C-free TRIP alloy, i.e., the yield strength increases from 165 ± 5 MPa to 220 ± 8 MPa, the ultimate tensile strength rises from 460 ± 5 MPa to 639 ± 8 MPa, and ∼36% of the total elongation. Systematic microstructure investigations were carried out before and after tensile deformation. It was found that C-doping in the C-TWIP alloy retains the TWIP effect while suppressing the dominant TRIP effect to the TWIP effect in the C-TRIP alloy. This work illustrates the role of C in the TWIP and TRIP-assisted HEAs and sheds some light on the design of high-performance alloys. The main highlights of the present work:•Carbon addition enhances FCC phase stability and increases the SFE of the TWIP and TRIP alloys.•Carbon addition overcomes the strength-ductility trade-off for TWIP and the TRIP alloys.•Carbon doping suppresses the TRIP effect and renders the interstitial strengthening and TWIP-assisted strengthening the dominant strengthening mechanisms.•Increasing SFE by interstitial addition is an effective path to elevate the strength and ductility of the HEAs simultaneously.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2022.144126