Formation of Core-Shell Type Structure in Duplex Martensitic Steel

EngRN: Engineering Design Process (Topic) Pub Date : 2020-10-05 DOI:10.2139/ssrn.3692024

K. Kaneko, T. Maeda, Y. Kawahara, Kazuhiro Ichino, T. Masumura, T. Tsuchiyama, H. Shirahata, R. Uemori

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引用次数: 4

Abstract

Abstract Microstructures of both as-quenched and intercritical-annealed medium-Mn steel were investigated by transmission electron microscopy to acquire a better understanding of γ–ɛ and γ–α′ martensitic transformations. The orientation relationships among each phases were determined as ( 1 ¯ 10 ) α ′ / / ( 0001 ) e , [ 111 ] α ′ / / [ 11 2 ¯ 0 ] e for the case of as-quenched sample, and ( 1 ¯ 10 ) α ′ / / ( 1 ¯ 11 ) γ / / ( 0001 ) e , [ 111 ] α ′ / / [ 110 ] γ / / [ 11 2 ¯ 0 ] e for the case of intercritical-annealed sample, respectively. In addition, the presences of core-shell type microstructures with the gradient of Mn concentration were confirmed with ɛ–martensite being surrounded by retained γ. Mn concentration of each phase was found dependent on the growth of reversed γ controlled by Mn diffusion during intercritical annealing. It was strongly suggested that the gradient of Mn concentration occurred during intercritical annealing affected the phase stability, which resulted in the formation of e/γ core-shell microstructures.

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双相马氏体钢核壳型组织的形成

摘要:采用透射电镜研究了淬火态和临界间退火态中mn钢的显微组织，以更好地理解γ - α′和γ - α′马氏体相变。每个阶段取向之间的关系被确定为(1¯10)α’/ / (0001)e,[111]α’/ /[11 2¯0]e淬火状态的样本的情况下,和(1¯10)α’/ /(1¯11)γ/ / (0001)e,[111]α’/ /[110]γ/ /[11 2¯0]e intercritical-annealed样本的情况下,分别。此外，随着Mn浓度的梯度，核壳型微结构的存在得到了证实，α -马氏体被保留的γ包围。在临界间退火过程中，各相的Mn浓度依赖于Mn扩散控制的反向γ的生长。结果表明，临界间退火过程中Mn浓度的梯度影响了相的稳定性，导致了e/γ核壳结构的形成。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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EngRN: Engineering Design Process (Topic)

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