TWIP effect and plastic instability condition in an Fe-Mn-C austenitic steel

Motomichi Koyama; Takahiro Sawaguchi; Kaneaki Tsuzaki

doi:10.2355/tetsutohagane.98.229

TWIP effect and plastic instability condition in an Fe-Mn-C austenitic steel

Motomichi Koyama, Takahiro Sawaguchi, Kaneaki Tsuzaki

IMR - Materials Design Division

Research output: Contribution to journal › Article › peer-review

11 Citations (Scopus)

Abstract

The correlation among deformation twin density, work hardening, and tensile ductility was investigated in an Fe-18Mn-1.2C steel. The twin density was varied by changing tensile deformation temperature from 123 to 523 K. The deformation twin density at a 10% plastic strain decreased with increasing deformation temperature except for the condition (123K) in which martensitic transformation occurred. The work hardening rate at the early deformation stage decreased due to the reduction in the deformation twin density; however, the decrease in work hardening rate did not affect the uniform elongation. The uniform elongation was determined by a plastic instability condition. Thus, the important factor for the uniform elongation is the work hardening rate in the later deformation stage. Additionally, we discussed influences of dynamic strain aging and e-martensitic transformation which accelerated fracture.

Original language	English
Pages (from-to)	229-236
Number of pages	8
Journal	Tetsu-To-Hagane/Journal of the Iron and Steel Institute of Japan
Volume	98
Issue number	6
DOIs	https://doi.org/10.2355/tetsutohagane.98.229
Publication status	Published - 2012

Keywords

Austenitic steel
Dynamic strain aging
High carbon
High Mn steel
Twinning induced plasticity
Work hardening

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10.2355/tetsutohagane.98.229

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title = "TWIP effect and plastic instability condition in an Fe-Mn-C austenitic steel",

abstract = "The correlation among deformation twin density, work hardening, and tensile ductility was investigated in an Fe-18Mn-1.2C steel. The twin density was varied by changing tensile deformation temperature from 123 to 523 K. The deformation twin density at a 10% plastic strain decreased with increasing deformation temperature except for the condition (123K) in which martensitic transformation occurred. The work hardening rate at the early deformation stage decreased due to the reduction in the deformation twin density; however, the decrease in work hardening rate did not affect the uniform elongation. The uniform elongation was determined by a plastic instability condition. Thus, the important factor for the uniform elongation is the work hardening rate in the later deformation stage. Additionally, we discussed influences of dynamic strain aging and e-martensitic transformation which accelerated fracture.",

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T1 - TWIP effect and plastic instability condition in an Fe-Mn-C austenitic steel

AU - Koyama, Motomichi

AU - Sawaguchi, Takahiro

AU - Tsuzaki, Kaneaki

PY - 2012

Y1 - 2012

N2 - The correlation among deformation twin density, work hardening, and tensile ductility was investigated in an Fe-18Mn-1.2C steel. The twin density was varied by changing tensile deformation temperature from 123 to 523 K. The deformation twin density at a 10% plastic strain decreased with increasing deformation temperature except for the condition (123K) in which martensitic transformation occurred. The work hardening rate at the early deformation stage decreased due to the reduction in the deformation twin density; however, the decrease in work hardening rate did not affect the uniform elongation. The uniform elongation was determined by a plastic instability condition. Thus, the important factor for the uniform elongation is the work hardening rate in the later deformation stage. Additionally, we discussed influences of dynamic strain aging and e-martensitic transformation which accelerated fracture.

AB - The correlation among deformation twin density, work hardening, and tensile ductility was investigated in an Fe-18Mn-1.2C steel. The twin density was varied by changing tensile deformation temperature from 123 to 523 K. The deformation twin density at a 10% plastic strain decreased with increasing deformation temperature except for the condition (123K) in which martensitic transformation occurred. The work hardening rate at the early deformation stage decreased due to the reduction in the deformation twin density; however, the decrease in work hardening rate did not affect the uniform elongation. The uniform elongation was determined by a plastic instability condition. Thus, the important factor for the uniform elongation is the work hardening rate in the later deformation stage. Additionally, we discussed influences of dynamic strain aging and e-martensitic transformation which accelerated fracture.

KW - Austenitic steel

KW - Dynamic strain aging

KW - High carbon

KW - High Mn steel

KW - Twinning induced plasticity

KW - Work hardening

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TWIP effect and plastic instability condition in an Fe-Mn-C austenitic steel

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Keywords

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