Optimizing strength and ductility in 2.8 wt% Mn TRIP steel: unlocking multistage TRIP effects through a co-deformable dual-heterogeneous structure

IF 7 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Science and Engineering: A Pub Date : 2025-10-03 DOI:10.1016/j.msea.2025.149212

Xiaodong Tan , Sihao Zou , Yuanping Xu , Junhua Hou , Jiawen Zhang , Jiatong Wang , Shengfeng Guo , Wenjun Lu

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Abstract

Achieving an optimal balance between strength and ductility in advanced high-strength steels (AHSS) remains a critical challenge, particularly for medium Mn TRIP steels, where high Mn content (≥5.0 wt%) often leads to severe Mn segregation, poor weldability, and high deformation resistance. Here, we demonstrate a novel co-deformable dual-heterogeneous structure in a low-carbon 2.8 wt% Mn TRIP steel, engineered through a combination of hot-rolling and tailored intercritical annealing strategies. This microstructural design, comprising polygonal ferrite, lath ferrite, and martensite/retained austenite (M/RA) islands with varying morphologies, delivers an exceptional product of strength and elongation (PSE) exceeding 30 GPa%, rivaling conventional high-Mn TRIP steels. A detailed microstructural investigation reveals that the material's superior mechanical performance stems from a multistage transformation-induced plasticity (TRIP) effect, governed by the sequential activation of strain localization across heterogeneous ferritic domains. Quasi in-situ EBSD and microscopic digital image correlation (μ-DIC) analyses uncover a strain partitioning cascade, where deformation first concentrates in polygonal ferrite, thick lath ferrite with high Schmid factors and local areas near the boundaries between lath ferrite blocks with significant crystallographic misorientation, then transitions through fine lath ferrite with high Schmid factors, before culminating in lath ferrite with lower Schmid factors. This orchestrated strain evolution triggers a progressive TRIP effect, effectively delaying strain localization and enhancing work-hardening capacity. Crucially, we show that the key to improved ductility is not merely the martensitic transformation of retained austenite, but rather the synchronized, co-deformable response of the ferritic matrix. These findings establish that strain localization engineering, through hierarchical microstructure design, is a powerful strategy for unlocking the full potential of TRIP steels. By integrating a controllable multistage TRIP effect via dual-heterostructure tuning, this study provides a blueprint for the next generation of low-carbon, low/medium Mn TRIP steels, offering an economically viable and industrially scalable alternative to conventional high-Mn AHSS.

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优化2.8 wt% Mn TRIP钢的强度和延展性：通过共变形双非均质结构解锁多级TRIP效应

在先进的高强度钢（AHSS）中实现强度和延展性之间的最佳平衡仍然是一个关键的挑战，特别是对于中等Mn的TRIP钢，高Mn含量（≥5.0 wt%）通常会导致严重的Mn偏析、焊接性差和高变形抗力。在这里，我们展示了一种新型的共变形双非均相结构，在低碳的2.8 wt% Mn TRIP钢中，通过热轧和定制的临界间退火策略相结合而设计。这种微结构设计包括多边形铁素体、板条铁素体和不同形态的马氏体/残余奥氏体（M/RA）岛，其强度和伸长率（PSE）超过30 GPa%，可与传统的高mn TRIP钢相媲美。详细的显微组织研究表明，该材料优越的力学性能源于多阶段相变诱导塑性（TRIP）效应，由非均质铁素体域应变局部化的顺序激活控制。准原位EBSD和显微数字图像相关（μ-DIC）分析揭示了一个应变分配级联，其中变形首先集中在多边形铁氧体、具有高施密德因子的厚板条铁氧体和板条铁氧体块边界附近具有明显晶体取向错误的区域，然后过渡到具有高施密德因子的细板条铁氧体，最后最终形成具有低施密德因子的板条铁氧体。这种精心安排的应变演化触发了渐进式的TRIP效应，有效地延缓了应变局部化并增强了加工硬化能力。至关重要的是，我们表明提高延展性的关键不仅仅是残余奥氏体的马氏体转变，而是铁素体基体的同步、共变形响应。这些发现表明，通过分层微观结构设计，应变局部化工程是释放TRIP钢全部潜力的有力策略。通过双异质结构调整整合可控的多级TRIP效应，该研究为下一代低碳、低/中锰TRIP钢提供了蓝图，为传统的高锰AHSS提供了经济上可行、工业上可扩展的替代方案。

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来源期刊

Materials Science and Engineering: A 工程技术-材料科学：综合

CiteScore

11.50

自引率

15.60%

发文量

1811

审稿时长

31 days

期刊介绍： Materials Science and Engineering A provides an international medium for the publication of theoretical and experimental studies related to the load-bearing capacity of materials as influenced by their basic properties, processing history, microstructure and operating environment. Appropriate submissions to Materials Science and Engineering A should include scientific and/or engineering factors which affect the microstructure - strength relationships of materials and report the changes to mechanical behavior.