Coopetitive micro-mechanisms between recrystallization and transformation during/after dynamic strain-induced transformation in aluminum-containing low-carbon steel

In this work, the coopetitive relationships among dynamic ferrite transformation, reverse ferrite transformation, and austenite recrystallization were investigated by using dynamic dilatometry, optical metallography, and electron backscattering diffraction in an aluminum-containing low-carbon steel...

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Bibliographic Details
Published in:Materials & design 2017-11, Vol.134, p.434-445
Main Authors: Chen, Shih-Che, Huang, Cheng-Yao, Wang, Yuan-Tsung, Yen, Hung-Wei
Format: Article
Language:English
Subjects:
Dynamic phenomena
EBSD
Phase transformation
Reconstruction
Recrystallization
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Summary:In this work, the coopetitive relationships among dynamic ferrite transformation, reverse ferrite transformation, and austenite recrystallization were investigated by using dynamic dilatometry, optical metallography, and electron backscattering diffraction in an aluminum-containing low-carbon steel subjected to hot compressions in the two-phase region. The microscopic mechanism of concurrent dynamic softening was studied based on the analysis of transformation crystallography. Moreover, this analysis method was used to discover the occurrence of reverse-transformation-induced recrystallization. In this microscopic mechanism, new austenite grains formed by reverse transformation can act as seeds for recrystallization. These paths for microstructural control in steels are not common, but they can be enabled by critical thermo-mechanical treatments combined with proper alloy design. [Display omitted] •Dynamic transformation and dynamic recrystallization were concurrently enabled in the aluminum‐containing low carbon steel.•Recrystallization assisted by reverse transformation was discovered, which breaks the limit of non-recrystallization temperature.•Transformation crystallography was applied to distinguish the sequence between transformation and recrystallization.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2017.08.074