Achieving superior ductility with ultrahigh strength via deformation and strain hardening in the non-recrystallized regions of the heterogeneous-structured high-entropy alloy

IF 8.3 1区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Acta Materialia Pub Date : 2024-11-14 DOI:10.1016/j.actamat.2024.120572
Hongchao Li, Jun Wang, Wenyuan Zhang, Jiawang Zhao, Jinshan Li, M.W. Fu
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Abstract

Developing metallic structural materials with ultra-high strength and exceptional ductility remains a significant challenge due to the trade-off between both properties. This study presents a heterogeneous-structured high-entropy alloy achieving a superior combination of strength and ductility compared to the reported heterogeneous-structured HEAs through deformation and strain hardening in the non-recrystallized regions. The cold rolling followed by annealing at 760°C resulted in a heterogeneous microstructure consisting of a small fraction of ultrafine recrystallized grains and extensive non-recrystallized regions, with a significant amount of L12 precipitates throughout the alloy. The architected microstructure led to a significant enhancement of yield strength through mechanisms including dislocation strengthening, L12 strengthening, and grain boundary strengthening. During the deformation, the non-recrystallized regions accommodated substantial strain through the reactivation of pre-existing deformation bands and the synergistic deformation of the FCC and L12 phases, thereby markedly enhancing ductility. Moreover, the metastable FCC matrix underwent FCC→BCC phase transformation, leading to the formation of numerous short-range BCC domains, which further contributed to the pronounced strain hardening. Consequently, the alloy annealing at 760 °C achieved a yield strength of 1.73 GPa, an ultimate strength of 2.05 GPa, and an elongation of 21.0%. This study underscores a novel strategy for the concurrent enhancement of strength and ductility and provides valuable insights for the design of high-performance alloys.

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通过在异质结构高熵合金的非再结晶区域进行变形和应变硬化,实现超高强度的卓越延展性
开发具有超高强度和超强延展性的金属结构材料仍然是一项重大挑战,因为这两种性能之间存在权衡。本研究介绍了一种异质结构高熵合金,与已报道的异质结构高熵合金相比,这种合金通过非再结晶区域的变形和应变硬化,实现了强度和延展性的完美结合。冷轧后在 760°C 下退火,形成了由少量超细再结晶晶粒和大量非再结晶区域组成的异质微观结构,整个合金中含有大量 L12 沉淀。通过位错强化、L12 强化和晶界强化等机制,这种结构化微观组织显著提高了屈服强度。在变形过程中,非重结晶区域通过重新激活先前存在的变形带以及 FCC 相和 L12 相的协同变形来容纳大量应变,从而显著提高了延展性。此外,可蜕变的 FCC 基体发生了 FCC→BCC 相变,形成了大量短程 BCC 域,进一步促进了明显的应变硬化。因此,在 760 °C 下退火的合金达到了 1.73 GPa 的屈服强度、2.05 GPa 的极限强度和 21.0% 的伸长率。这项研究强调了同时提高强度和延展性的新策略,并为高性能合金的设计提供了宝贵的见解。
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来源期刊
Acta Materialia
Acta Materialia 工程技术-材料科学:综合
CiteScore
16.10
自引率
8.50%
发文量
801
审稿时长
53 days
期刊介绍: Acta Materialia serves as a platform for publishing full-length, original papers and commissioned overviews that contribute to a profound understanding of the correlation between the processing, structure, and properties of inorganic materials. The journal seeks papers with high impact potential or those that significantly propel the field forward. The scope includes the atomic and molecular arrangements, chemical and electronic structures, and microstructure of materials, focusing on their mechanical or functional behavior across all length scales, including nanostructures.
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