The role of aluminium in chemical and phase segregation in a TRIP-assisted dual phase steel

B. L. Ennis; E. Jimenez-Melero; R. Mostert; B. Santillana; P. D. Lee

doi:10.1016/j.actamat.2016.05.046

The role of aluminium in chemical and phase segregation in a TRIP-assisted dual phase steel

B. L. Ennis^*, E. Jimenez-Melero, R. Mostert, B. Santillana, P. D. Lee

^*Corresponding author for this work

Metallurgy and Materials

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

Abstract

In this work we demonstrate that micro-segregation patterns of alloying elements present in a high-strength TRIP-assisted DP steel after casting are retained in the microstructure throughout processing, and lead to anisotropy (banding) in the final microstructure. In particular, we have assessed the role of Al on the chemical segregation of Mn, Cr and Si during casting, and their impact on the phase transformations occurring during thermo-mechanical processing of the as-cast material. We have derived the elemental partition coefficients, based on the experimentally determined dendrite spacing and chemical profiles in the as-cast structure, and used them to derive the local austenite-to-ferrite transformation temperature. Our cellular automaton methodology to simulate phase transformations allows reliable prediction of the formation or suppression of banding in the intermediate and final microstructures for different heating or cooling rates. Our results reveal that aluminium exerts the largest individual effect of the substitutional elements on the formation of banding in these steels. Controlling micro-segregation during solidification in advanced high-strength multiphase steels is therefore critical for obtaining homogeneous mechanical properties in the final product, as it controls the phase transformations occurring during thermo-mechanical processing and therefore the final microstructure.

Original language	English
Pages (from-to)	132-142
Number of pages	11
Journal	Acta Materialia
Volume	115
DOIs	https://doi.org/10.1016/j.actamat.2016.05.046
Publication status	Published - 15 Aug 2016

Bibliographical note

Funding Information:
This work was made possible by the facilities and support of Tata Steel, the Diamond-Manchester Collaboration and the Research Complex at Harwell, funded in part by the EPSRC ( EP/I02249X/1 ). The authors gratefully acknowledge Dr. Marco Rijnders for EPMA analysis, Dr. Kees Bos for the CA model calculations and Mrs. Tu Phan Tran for assistance with the microstructural characterisation. Further thanks are due to Prof. In-Ho Jung at McGill University for assistance with FactSage.

Publisher Copyright:
© 2016 Published by Elsevier Ltd on behalf of Acta Materialia Inc. All rights reserved.

Keywords

Casting
Chemical segregation
Phase transformation
Steel
Thermo-mechanical processing

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Ceramics and Composites
Polymers and Plastics
Metals and Alloys

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10.1016/j.actamat.2016.05.046

Cite this

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title = "The role of aluminium in chemical and phase segregation in a TRIP-assisted dual phase steel",

abstract = "In this work we demonstrate that micro-segregation patterns of alloying elements present in a high-strength TRIP-assisted DP steel after casting are retained in the microstructure throughout processing, and lead to anisotropy (banding) in the final microstructure. In particular, we have assessed the role of Al on the chemical segregation of Mn, Cr and Si during casting, and their impact on the phase transformations occurring during thermo-mechanical processing of the as-cast material. We have derived the elemental partition coefficients, based on the experimentally determined dendrite spacing and chemical profiles in the as-cast structure, and used them to derive the local austenite-to-ferrite transformation temperature. Our cellular automaton methodology to simulate phase transformations allows reliable prediction of the formation or suppression of banding in the intermediate and final microstructures for different heating or cooling rates. Our results reveal that aluminium exerts the largest individual effect of the substitutional elements on the formation of banding in these steels. Controlling micro-segregation during solidification in advanced high-strength multiphase steels is therefore critical for obtaining homogeneous mechanical properties in the final product, as it controls the phase transformations occurring during thermo-mechanical processing and therefore the final microstructure.",

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note = "Funding Information: This work was made possible by the facilities and support of Tata Steel, the Diamond-Manchester Collaboration and the Research Complex at Harwell, funded in part by the EPSRC ( EP/I02249X/1 ). The authors gratefully acknowledge Dr. Marco Rijnders for EPMA analysis, Dr. Kees Bos for the CA model calculations and Mrs. Tu Phan Tran for assistance with the microstructural characterisation. Further thanks are due to Prof. In-Ho Jung at McGill University for assistance with FactSage. Publisher Copyright: {\textcopyright} 2016 Published by Elsevier Ltd on behalf of Acta Materialia Inc. All rights reserved.",

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AU - Jimenez-Melero, E.

AU - Mostert, R.

AU - Santillana, B.

AU - Lee, P. D.

N1 - Funding Information: This work was made possible by the facilities and support of Tata Steel, the Diamond-Manchester Collaboration and the Research Complex at Harwell, funded in part by the EPSRC ( EP/I02249X/1 ). The authors gratefully acknowledge Dr. Marco Rijnders for EPMA analysis, Dr. Kees Bos for the CA model calculations and Mrs. Tu Phan Tran for assistance with the microstructural characterisation. Further thanks are due to Prof. In-Ho Jung at McGill University for assistance with FactSage. Publisher Copyright: © 2016 Published by Elsevier Ltd on behalf of Acta Materialia Inc. All rights reserved.

PY - 2016/8/15

Y1 - 2016/8/15

N2 - In this work we demonstrate that micro-segregation patterns of alloying elements present in a high-strength TRIP-assisted DP steel after casting are retained in the microstructure throughout processing, and lead to anisotropy (banding) in the final microstructure. In particular, we have assessed the role of Al on the chemical segregation of Mn, Cr and Si during casting, and their impact on the phase transformations occurring during thermo-mechanical processing of the as-cast material. We have derived the elemental partition coefficients, based on the experimentally determined dendrite spacing and chemical profiles in the as-cast structure, and used them to derive the local austenite-to-ferrite transformation temperature. Our cellular automaton methodology to simulate phase transformations allows reliable prediction of the formation or suppression of banding in the intermediate and final microstructures for different heating or cooling rates. Our results reveal that aluminium exerts the largest individual effect of the substitutional elements on the formation of banding in these steels. Controlling micro-segregation during solidification in advanced high-strength multiphase steels is therefore critical for obtaining homogeneous mechanical properties in the final product, as it controls the phase transformations occurring during thermo-mechanical processing and therefore the final microstructure.

AB - In this work we demonstrate that micro-segregation patterns of alloying elements present in a high-strength TRIP-assisted DP steel after casting are retained in the microstructure throughout processing, and lead to anisotropy (banding) in the final microstructure. In particular, we have assessed the role of Al on the chemical segregation of Mn, Cr and Si during casting, and their impact on the phase transformations occurring during thermo-mechanical processing of the as-cast material. We have derived the elemental partition coefficients, based on the experimentally determined dendrite spacing and chemical profiles in the as-cast structure, and used them to derive the local austenite-to-ferrite transformation temperature. Our cellular automaton methodology to simulate phase transformations allows reliable prediction of the formation or suppression of banding in the intermediate and final microstructures for different heating or cooling rates. Our results reveal that aluminium exerts the largest individual effect of the substitutional elements on the formation of banding in these steels. Controlling micro-segregation during solidification in advanced high-strength multiphase steels is therefore critical for obtaining homogeneous mechanical properties in the final product, as it controls the phase transformations occurring during thermo-mechanical processing and therefore the final microstructure.

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The role of aluminium in chemical and phase segregation in a TRIP-assisted dual phase steel

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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