Exceptional strength-ductility synergy in the novel metastable FeCoCrNiVSi high-entropy alloys via tuning the grain size dependency of the transformation-induced plasticity effect

IF 9.4 1区 材料科学 Q1 ENGINEERING, MECHANICAL International Journal of Plasticity Pub Date : 2024-09-02 DOI:10.1016/j.ijplas.2024.104115
Mohammad Sajad Mehranpour , Mohammad Javad Sohrabi , Alireza Kalhor , Jae Heung Lee , Ali Heydarinia , Hamed Mirzadeh , Saeed Sadeghpour , Kinga Rodak , Mahmoud Nili-Ahmadabadi , Reza Mahmudi , Hyoung Seop Kim
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Abstract

In-depth knowledge of the coupling between grain refinement and the transformation-induced plasticity (TRIP) effect in metastable alloys is a viable approach for the improvement of strength-ductility synergy, which needs systematic research with consideration of commercial austenitic stainless steels and novel high-entropy alloys (HEAs). Accordingly, in the present work, two Si-containing metastable HEAs in the Fe47Co30Cr10Ni5V8-xSix system (x = 3 and 6 at.%) were designed, and the TRIP-assisted AISI 304L stainless steel was also considered for comparison. The alloys were processed by cold rolling and annealing to obtain different grain sizes. Reducing the stacking fault energy (SFE) through adjusting chemical composition contributes to minimizing the detrimental effect of grain refinement on the ductility of TRIP alloys, while extremely low SFE must be avoided owing to the fast kinetics of deformation-induced martensitic phase transformation, which leads to the deterioration of ductility. In contrast to AISI 304L stainless steel, a strong TRIP effect was maintained upon grain refinement in the Fe47Co30Cr10Ni5V2Si6 HEA due to the remaining apparent SFE in the appropriate TRIP range. The tuned kinetics of martensitic transformation was found to be responsible for the exceptional ductility (∼65 %) of Fe47Co30Cr10Ni5V2Si6 HEA at an ultrahigh tensile strength of ∼1230 MPa. Therefore, considering the identical trend of SFE with grain size, an appropriate initial SFE value is important for tuning the grain size dependency of the TRIP effect. Moreover, the ultrahigh strength was attributed to the high volume fraction of α΄-martensite as well as the high strength of the martensite phase due to the high Si content. Accordingly, for achieving strong-yet-ductile HEAs, a high Si content is recommended to benefit from solid solution strengthening in the martensite phase, a specially-designed chemical composition is needed for attaining a high volume fraction of α΄-martensite, and SFE should be in a desirable range to tune the kinetics of martensitic phase transformation.

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通过调整转变诱导塑性效应的晶粒尺寸相关性,在新型可蜕变铁铬镍硅高熵合金中实现优异的强度-韧性协同效应
深入了解可代谢合金中晶粒细化与转化诱导塑性(TRIP)效应之间的耦合关系是提高强度-电导率协同效应的可行方法,这需要对商业奥氏体不锈钢和新型高熵合金(HEAs)进行系统研究。因此,在本研究中,设计了 Fe47Co30Cr10Ni5V8-xSix 体系(x = 3 和 6 at.%)中的两种含 Si- 的易析出高熵合金,并将 TRIP 辅助的 AISI 304L 不锈钢作为比较对象。合金经过冷轧和退火处理,以获得不同的晶粒大小。通过调整化学成分降低堆叠错能(SFE)有助于最大限度地减少晶粒细化对 TRIP 合金延展性的不利影响,同时必须避免极低的 SFE,因为形变引起的马氏体相变的动力学速度很快,会导致延展性恶化。与 AISI 304L 不锈钢相比,Fe47Co30Cr10Ni5V2Si6 HEA 在晶粒细化后仍能保持较强的 TRIP 效应,这是因为在适当的 TRIP 范围内仍存在表观 SFE。经过调整的马氏体转变动力学被认为是 Fe47Co30Cr10Ni5V2Si6 HEA 在 1230 MPa 的超高拉伸强度下具有优异延展性(∼65 %)的原因。因此,考虑到 SFE 随晶粒尺寸变化的相同趋势,适当的初始 SFE 值对于调整 TRIP 效应的晶粒尺寸依赖性非常重要。此外,超高强度还归因于α΄-马氏体的高体积分数以及高硅含量导致的马氏体相的高强度。因此,要获得强度高但韧性好的 HEA,建议采用高硅含量,以受益于马氏体相的固溶强化;需要专门设计的化学成分,以获得高体积分数的 α΄-马氏体;SFE 应在理想范围内,以调整马氏体相变的动力学。
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来源期刊
International Journal of Plasticity
International Journal of Plasticity 工程技术-材料科学:综合
CiteScore
15.30
自引率
26.50%
发文量
256
审稿时长
46 days
期刊介绍: International Journal of Plasticity aims to present original research encompassing all facets of plastic deformation, damage, and fracture behavior in both isotropic and anisotropic solids. This includes exploring the thermodynamics of plasticity and fracture, continuum theory, and macroscopic as well as microscopic phenomena. Topics of interest span the plastic behavior of single crystals and polycrystalline metals, ceramics, rocks, soils, composites, nanocrystalline and microelectronics materials, shape memory alloys, ferroelectric ceramics, thin films, and polymers. Additionally, the journal covers plasticity aspects of failure and fracture mechanics. Contributions involving significant experimental, numerical, or theoretical advancements that enhance the understanding of the plastic behavior of solids are particularly valued. Papers addressing the modeling of finite nonlinear elastic deformation, bearing similarities to the modeling of plastic deformation, are also welcomed.
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