Strain aging characterization and physical modelling of over-aging in dual phase steel

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Strain aging characterization and physical modelling of over-aging in dual phase steel. / Soliman, Mohamed; Shan, Yao V.; Mendez Martin, Francisca et al.
in: Materials science and engineering: A, Structural materials: properties, microstructure and processing, Jahrgang 788.2020, Nr. 24 June, 139595, 24.06.2020.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

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@article{04af293d5abb46d78fb51bd666410c41,
title = "Strain aging characterization and physical modelling of over-aging in dual phase steel",
abstract = "This study presents an integrated work of experimental investigations and physical modeling of bake hardening (BH) response in dual-phase steel (DP). A DP steel with a martensite volume percentage of 22% was produced by intercritical annealing followed by quenching in brine. Aging experiments with up to 5% pre-straining were carried out in the temperature range of 100 to 220 °C, for 2 to 2·10 4 min at temperature. The DP steel was characterized using light optical, scanning electron and transmission electron microscopy. The pinning effect of the dislocations was revealed by atom probe tomographic analysis. The increase in the yield strength accompanying the aging phenomenon, measured using tensile tests, showed a two-step increase, followed by an over-aging stage. The dependence of the time-interval of each stage on the pre-strain value and aging temperature was analyzed. A physical-based model for interpreting the over-aging stage in DP steel was developed. A new concept for over-aging, correlating it to carbon-diffusion from ferrite to martensite due to the gradient in the chemical potential at the interface between the two phases, was introduced. This diffusion causes a partial dissolution of the already formed Cottrell atmosphere/carbide precipitates. Finally, the time required for the onset of over-aging, calculated using physical simulations, was compared with experimental results showing a good matching between experiment and simulation. ",
author = "Mohamed Soliman and Shan, {Yao V.} and {Mendez Martin}, Francisca and Ernst Kozeschnik and Heinz Palkowski",
note = "Publisher Copyright: {\textcopyright} 2020 Elsevier B.V.",
year = "2020",
month = jun,
day = "24",
doi = "10.1016/j.msea.2020.139595",
language = "English",
volume = "788.2020",
journal = "Materials science and engineering: A, Structural materials: properties, microstructure and processing",
issn = "0921-5093",
publisher = "Elsevier",
number = "24 June",

}

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TY - JOUR

T1 - Strain aging characterization and physical modelling of over-aging in dual phase steel

AU - Soliman, Mohamed

AU - Shan, Yao V.

AU - Mendez Martin, Francisca

AU - Kozeschnik, Ernst

AU - Palkowski, Heinz

N1 - Publisher Copyright: © 2020 Elsevier B.V.

PY - 2020/6/24

Y1 - 2020/6/24

N2 - This study presents an integrated work of experimental investigations and physical modeling of bake hardening (BH) response in dual-phase steel (DP). A DP steel with a martensite volume percentage of 22% was produced by intercritical annealing followed by quenching in brine. Aging experiments with up to 5% pre-straining were carried out in the temperature range of 100 to 220 °C, for 2 to 2·10 4 min at temperature. The DP steel was characterized using light optical, scanning electron and transmission electron microscopy. The pinning effect of the dislocations was revealed by atom probe tomographic analysis. The increase in the yield strength accompanying the aging phenomenon, measured using tensile tests, showed a two-step increase, followed by an over-aging stage. The dependence of the time-interval of each stage on the pre-strain value and aging temperature was analyzed. A physical-based model for interpreting the over-aging stage in DP steel was developed. A new concept for over-aging, correlating it to carbon-diffusion from ferrite to martensite due to the gradient in the chemical potential at the interface between the two phases, was introduced. This diffusion causes a partial dissolution of the already formed Cottrell atmosphere/carbide precipitates. Finally, the time required for the onset of over-aging, calculated using physical simulations, was compared with experimental results showing a good matching between experiment and simulation.

AB - This study presents an integrated work of experimental investigations and physical modeling of bake hardening (BH) response in dual-phase steel (DP). A DP steel with a martensite volume percentage of 22% was produced by intercritical annealing followed by quenching in brine. Aging experiments with up to 5% pre-straining were carried out in the temperature range of 100 to 220 °C, for 2 to 2·10 4 min at temperature. The DP steel was characterized using light optical, scanning electron and transmission electron microscopy. The pinning effect of the dislocations was revealed by atom probe tomographic analysis. The increase in the yield strength accompanying the aging phenomenon, measured using tensile tests, showed a two-step increase, followed by an over-aging stage. The dependence of the time-interval of each stage on the pre-strain value and aging temperature was analyzed. A physical-based model for interpreting the over-aging stage in DP steel was developed. A new concept for over-aging, correlating it to carbon-diffusion from ferrite to martensite due to the gradient in the chemical potential at the interface between the two phases, was introduced. This diffusion causes a partial dissolution of the already formed Cottrell atmosphere/carbide precipitates. Finally, the time required for the onset of over-aging, calculated using physical simulations, was compared with experimental results showing a good matching between experiment and simulation.

UR - http://www.scopus.com/inward/record.url?scp=85085524487&partnerID=8YFLogxK

U2 - 10.1016/j.msea.2020.139595

DO - 10.1016/j.msea.2020.139595

M3 - Article

VL - 788.2020

JO - Materials science and engineering: A, Structural materials: properties, microstructure and processing

JF - Materials science and engineering: A, Structural materials: properties, microstructure and processing

SN - 0921-5093

IS - 24 June

M1 - 139595

ER -