Analysis of the mechanical behavior of a 0.3C-1.6Si-3.5Mn (wt%) quenching and partitioning steel

Farideh Hajy Akbary; Jilt Sietsma; Goro Miyamoto; N. Kamikawa; Roumen Petrov; T Furuhara; Maria Santofimia Navarro

doi:10.1016/j.msea.2016.09.087

Analysis of the mechanical behavior of a 0.3C-1.6Si-3.5Mn (wt%) quenching and partitioning steel

Farideh Hajy Akbary, Jilt Sietsma, Goro Miyamoto, N. Kamikawa , Roumen Petrov, T Furuhara, Maria Santofimia Navarro

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

60 Citations (Scopus)

Abstract

A 0.3C-1.6Si-3.5Mn (wt%) steel was subjected to different Q&P treatments, leading to different combinations of initial martensite, bainite, secondary martensite, and retained austenite. In this study, initial martensite refers to the martensite formed during the initial quenching step and then subjected to an isothermal treatment at 400 °C; secondary martensite refers to martensite formed during quenching from 400 °C to room temperature. The yield strength of each constituent phase was determined by applying physical models to the data obtained from detailed microstructural characterization. The yield strength (uncertainty of 5%) of the Q&P microstructures was calculated by using a composite law to account for the contribution of each constituent phase. The dependence of the yield strength on the microstructural features of the Q&P microstructures was revealed by using the approach developed in this work. For example, initial martensite (which has a high yield strength and is the dominant phase in the microstructures) had the greatest effect on the yield strength of the Q&P microstructures. Furthermore, the phase fraction and dislocation density of this phase increased with decreasing quenching temperature, leading to an increase in the yield strength of the material.

Original language	English
Pages (from-to)	505–514
Journal	Materials Science and Engineering A: Structural Materials: Properties, Microstructures and Processing
Volume	677
DOIs	https://doi.org/10.1016/j.msea.2016.09.087
Publication status	Published - 2016

Keywords

Quenching and partitioning steels
Yield strength
Strengthening mechanism
Dislocation density
Martensite

Access to Document

10.1016/j.msea.2016.09.087

Cite this

Hajy Akbary, F., Sietsma, J., Miyamoto, G., Kamikawa , N., Petrov, R., Furuhara, T., & Santofimia Navarro, M. (2016). Analysis of the mechanical behavior of a 0.3C-1.6Si-3.5Mn (wt%) quenching and partitioning steel. Materials Science and Engineering A: Structural Materials: Properties, Microstructures and Processing, 677, 505–514. https://doi.org/10.1016/j.msea.2016.09.087

@article{98511f02164b4d9ba4af687aa0ded633,

title = "Analysis of the mechanical behavior of a 0.3C-1.6Si-3.5Mn (wt%) quenching and partitioning steel",

abstract = "A 0.3C-1.6Si-3.5Mn (wt%) steel was subjected to different Q&P treatments, leading to different combinations of initial martensite, bainite, secondary martensite, and retained austenite. In this study, initial martensite refers to the martensite formed during the initial quenching step and then subjected to an isothermal treatment at 400 °C; secondary martensite refers to martensite formed during quenching from 400 °C to room temperature. The yield strength of each constituent phase was determined by applying physical models to the data obtained from detailed microstructural characterization. The yield strength (uncertainty of 5%) of the Q&P microstructures was calculated by using a composite law to account for the contribution of each constituent phase. The dependence of the yield strength on the microstructural features of the Q&P microstructures was revealed by using the approach developed in this work. For example, initial martensite (which has a high yield strength and is the dominant phase in the microstructures) had the greatest effect on the yield strength of the Q&P microstructures. Furthermore, the phase fraction and dislocation density of this phase increased with decreasing quenching temperature, leading to an increase in the yield strength of the material.",

keywords = "Quenching and partitioning steels, Yield strength, Strengthening mechanism, Dislocation density, Martensite",

author = "{Hajy Akbary}, Farideh and Jilt Sietsma and Goro Miyamoto and N. Kamikawa and Roumen Petrov and T Furuhara and {Santofimia Navarro}, Maria",

year = "2016",

doi = "10.1016/j.msea.2016.09.087",

language = "English",

volume = "677",

pages = "505–514",

journal = "Materials Science and Engineering A: Structural Materials: Properties, Microstructures and Processing",

issn = "0921-5093",

publisher = "Elsevier",

}

Hajy Akbary, F, Sietsma, J, Miyamoto, G, Kamikawa , N, Petrov, R, Furuhara, T & Santofimia Navarro, M 2016, 'Analysis of the mechanical behavior of a 0.3C-1.6Si-3.5Mn (wt%) quenching and partitioning steel', Materials Science and Engineering A: Structural Materials: Properties, Microstructures and Processing, vol. 677, pp. 505–514. https://doi.org/10.1016/j.msea.2016.09.087

Analysis of the mechanical behavior of a 0.3C-1.6Si-3.5Mn (wt%) quenching and partitioning steel. / Hajy Akbary, Farideh; Sietsma, Jilt; Miyamoto, Goro et al.
In: Materials Science and Engineering A: Structural Materials: Properties, Microstructures and Processing, Vol. 677, 2016, p. 505–514.

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

TY - JOUR

T1 - Analysis of the mechanical behavior of a 0.3C-1.6Si-3.5Mn (wt%) quenching and partitioning steel

AU - Hajy Akbary, Farideh

AU - Sietsma, Jilt

AU - Miyamoto, Goro

AU - Kamikawa , N.

AU - Petrov, Roumen

AU - Furuhara, T

AU - Santofimia Navarro, Maria

PY - 2016

Y1 - 2016

N2 - A 0.3C-1.6Si-3.5Mn (wt%) steel was subjected to different Q&P treatments, leading to different combinations of initial martensite, bainite, secondary martensite, and retained austenite. In this study, initial martensite refers to the martensite formed during the initial quenching step and then subjected to an isothermal treatment at 400 °C; secondary martensite refers to martensite formed during quenching from 400 °C to room temperature. The yield strength of each constituent phase was determined by applying physical models to the data obtained from detailed microstructural characterization. The yield strength (uncertainty of 5%) of the Q&P microstructures was calculated by using a composite law to account for the contribution of each constituent phase. The dependence of the yield strength on the microstructural features of the Q&P microstructures was revealed by using the approach developed in this work. For example, initial martensite (which has a high yield strength and is the dominant phase in the microstructures) had the greatest effect on the yield strength of the Q&P microstructures. Furthermore, the phase fraction and dislocation density of this phase increased with decreasing quenching temperature, leading to an increase in the yield strength of the material.

AB - A 0.3C-1.6Si-3.5Mn (wt%) steel was subjected to different Q&P treatments, leading to different combinations of initial martensite, bainite, secondary martensite, and retained austenite. In this study, initial martensite refers to the martensite formed during the initial quenching step and then subjected to an isothermal treatment at 400 °C; secondary martensite refers to martensite formed during quenching from 400 °C to room temperature. The yield strength of each constituent phase was determined by applying physical models to the data obtained from detailed microstructural characterization. The yield strength (uncertainty of 5%) of the Q&P microstructures was calculated by using a composite law to account for the contribution of each constituent phase. The dependence of the yield strength on the microstructural features of the Q&P microstructures was revealed by using the approach developed in this work. For example, initial martensite (which has a high yield strength and is the dominant phase in the microstructures) had the greatest effect on the yield strength of the Q&P microstructures. Furthermore, the phase fraction and dislocation density of this phase increased with decreasing quenching temperature, leading to an increase in the yield strength of the material.

KW - Quenching and partitioning steels

KW - Yield strength

KW - Strengthening mechanism

KW - Dislocation density

KW - Martensite

U2 - 10.1016/j.msea.2016.09.087

DO - 10.1016/j.msea.2016.09.087

M3 - Article

SN - 0921-5093

VL - 677

SP - 505

EP - 514

JO - Materials Science and Engineering A: Structural Materials: Properties, Microstructures and Processing

JF - Materials Science and Engineering A: Structural Materials: Properties, Microstructures and Processing

ER -

Analysis of the mechanical behavior of a 0.3C-1.6Si-3.5Mn (wt%) quenching and partitioning steel

Abstract

Keywords

Access to Document

Fingerprint

Cite this