Microstructurally Based Modeling of Creep Deformation and Damage in Martensitic Steels

Christof Sommitsch; Bernhard Sonderegger; Mohammad Reza Ahmadi; Florian Riedlsperger; Felix Meixner; Josef Mergl; Bernhard Krenmayr

doi:10.5772/intechopen.104381

Microstructurally Based Modeling of Creep Deformation and Damage in Martensitic Steels

Christof Sommitsch^*, Bernhard Sonderegger, Mohammad Reza Ahmadi, Florian Riedlsperger, Felix Meixner, Josef Mergl, Bernhard Krenmayr

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

This chapter deals with modeling the microstructural evolution, creep deformation, and pore formation in creep-resistant martensitic 9–12% Cr steels. Apart from the stress and temperature exposure of the material, the input parameters for the models are as-received microstructure and one single-creep experiment of moderate duration. The models provide predictive results on deformation rates and microstructure degradation over a wide stress range. Due to their link to the underlying fundamental physical processes such as classical nucleation theory, Gibbs energy dissipation, climb, and glide of dislocations, etc., the models are applicable to any martensitic steel with similar microstructure to the presented case study. Note that we section the chapter into part 1: creep deformation and part 2: pore formation.

Original language	English
Title of host publication	Creep Deformation
Editors	Zak Abdallah, Nada Aldoumani
Place of Publication	London
Publisher	IntechOpen
DOIs	https://doi.org/10.5772/intechopen.104381
Publication status	E-pub ahead of print - 21 Apr 2022

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10.5772/intechopen.104381Licence: CC BY 4.0

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title = "Microstructurally Based Modeling of Creep Deformation and Damage in Martensitic Steels",

abstract = "This chapter deals with modeling the microstructural evolution, creep deformation, and pore formation in creep-resistant martensitic 9–12% Cr steels. Apart from the stress and temperature exposure of the material, the input parameters for the models are as-received microstructure and one single-creep experiment of moderate duration. The models provide predictive results on deformation rates and microstructure degradation over a wide stress range. Due to their link to the underlying fundamental physical processes such as classical nucleation theory, Gibbs energy dissipation, climb, and glide of dislocations, etc., the models are applicable to any martensitic steel with similar microstructure to the presented case study. Note that we section the chapter into part 1: creep deformation and part 2: pore formation.",

author = "Christof Sommitsch and Bernhard Sonderegger and Ahmadi, {Mohammad Reza} and Florian Riedlsperger and Felix Meixner and Josef Mergl and Bernhard Krenmayr",

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AU - Sommitsch, Christof

AU - Sonderegger, Bernhard

AU - Ahmadi, Mohammad Reza

AU - Riedlsperger, Florian

AU - Meixner, Felix

AU - Mergl, Josef

AU - Krenmayr, Bernhard

PY - 2022/4/21

Y1 - 2022/4/21

N2 - This chapter deals with modeling the microstructural evolution, creep deformation, and pore formation in creep-resistant martensitic 9–12% Cr steels. Apart from the stress and temperature exposure of the material, the input parameters for the models are as-received microstructure and one single-creep experiment of moderate duration. The models provide predictive results on deformation rates and microstructure degradation over a wide stress range. Due to their link to the underlying fundamental physical processes such as classical nucleation theory, Gibbs energy dissipation, climb, and glide of dislocations, etc., the models are applicable to any martensitic steel with similar microstructure to the presented case study. Note that we section the chapter into part 1: creep deformation and part 2: pore formation.

AB - This chapter deals with modeling the microstructural evolution, creep deformation, and pore formation in creep-resistant martensitic 9–12% Cr steels. Apart from the stress and temperature exposure of the material, the input parameters for the models are as-received microstructure and one single-creep experiment of moderate duration. The models provide predictive results on deformation rates and microstructure degradation over a wide stress range. Due to their link to the underlying fundamental physical processes such as classical nucleation theory, Gibbs energy dissipation, climb, and glide of dislocations, etc., the models are applicable to any martensitic steel with similar microstructure to the presented case study. Note that we section the chapter into part 1: creep deformation and part 2: pore formation.

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DO - 10.5772/intechopen.104381

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BT - Creep Deformation

A2 - Abdallah, Zak

A2 - Aldoumani, Nada

PB - IntechOpen

CY - London

ER -

Microstructurally Based Modeling of Creep Deformation and Damage in Martensitic Steels

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