Estimation of austenite grain boundary mobility in low-carbon steel by grain growth

The temporal evolution of grain size distribution (GSD) was observed by EBSD IPF maps of austenite reconstructed from the orientation maps of martensite in Fe–0.1C and Fe–0.1C–3Mn alloys from which the spatial GSD was predicted by the Saltykov method. They were compared with grain growth simulation...

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Veröffentlicht in:	Journal of materials science 2023-03, Vol.58 (10), p.4603-4620
Hauptverfasser:	Enomoto, Masato, Hayashi, Koutarou
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Sprache:	eng
Schlagworte:	Alloys Analysis Austenite carbon Carbon steel Characterization and Evaluation of Materials Chemistry and Materials Science Classical Mechanics Crystallography and Scattering Methods Diffusion coefficient Diffusivity ferrimagnetic materials Grain boundaries Grain boundary diffusion Grain growth Grain size distribution Iron compounds Low carbon steels Martensite Materials Science Metals & Corrosion particle size distribution Polymer Sciences Solid Mechanics solutes steel Steel, Structural
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description	The temporal evolution of grain size distribution (GSD) was observed by EBSD IPF maps of austenite reconstructed from the orientation maps of martensite in Fe–0.1C and Fe–0.1C–3Mn alloys from which the spatial GSD was predicted by the Saltykov method. They were compared with grain growth simulation by Abbruzzese and Lücke (A–L) model. The mobility of grain boundary in the Fe–0.1C alloy was estimated to be three to four orders of magnitude lower than those of ferrite grain boundaries of high-purity Fe, similar to or somewhat lower than the higher values of α / γ interface reported so far. The spatial GSD and average grain radius in the Fe–0.1C–3Mn alloy were compared with the A–L model in which solute drag caused by carbon and Mn segregation was incorporated. The grain growth rate was reproduced with the Mn diffusivity across a grain boundary, i.e. trans-grain boundary diffusion coefficient, lying between the volume diffusivity of Mn in austenite and the diffusivity along the grain boundary.
doi_str_mv	10.1007/s10853-023-08284-y
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They were compared with grain growth simulation by Abbruzzese and Lücke (A–L) model. The mobility of grain boundary in the Fe–0.1C alloy was estimated to be three to four orders of magnitude lower than those of ferrite grain boundaries of high-purity Fe, similar to or somewhat lower than the higher values of α / γ interface reported so far. The spatial GSD and average grain radius in the Fe–0.1C–3Mn alloy were compared with the A–L model in which solute drag caused by carbon and Mn segregation was incorporated. 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They were compared with grain growth simulation by Abbruzzese and Lücke (A–L) model. The mobility of grain boundary in the Fe–0.1C alloy was estimated to be three to four orders of magnitude lower than those of ferrite grain boundaries of high-purity Fe, similar to or somewhat lower than the higher values of α / γ interface reported so far. The spatial GSD and average grain radius in the Fe–0.1C–3Mn alloy were compared with the A–L model in which solute drag caused by carbon and Mn segregation was incorporated. 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subjects	Alloys Analysis Austenite carbon Carbon steel Characterization and Evaluation of Materials Chemistry and Materials Science Classical Mechanics Crystallography and Scattering Methods Diffusion coefficient Diffusivity ferrimagnetic materials Grain boundaries Grain boundary diffusion Grain growth Grain size distribution Iron compounds Low carbon steels Martensite Materials Science Metals & Corrosion particle size distribution Polymer Sciences Solid Mechanics solutes steel Steel, Structural
title	Estimation of austenite grain boundary mobility in low-carbon steel by grain growth
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