A dislocation-based model for high temperature cyclic viscoplasticity of 9-12Cr steels

R. A. Barrett; P. E. O'Donoghue; S. B. Leen

doi:10.1016/j.commatsci.2014.05.034

A dislocation-based model for high temperature cyclic viscoplasticity of 9-12Cr steels

R. A. Barrett, P. E. O'Donoghue, S. B. Leen

Research output: Contribution to a Journal (Peer & Non Peer) › Article › peer-review

62 Citations (Scopus)

Abstract

A dislocation-based model for high temperature cyclic viscoplasticity in 9-12Cr steels is presented. This model incorporates (i) cyclic softening via decrease in overall dislocation density, loss of low angle boundary dislocations and coarsening of the microstructure and (ii) kinematic hardening via precipitate strengthening and dislocation substructure hardening. The effects of the primary micro-structural variables, viz. precipitate radii, dislocation density and martensitic lath width on cyclic viscoplasticity, reveal a size effect of initial precipitate radii and volume fraction, with smaller radii and a higher density of precipitate producing a stronger material. A similar effect is also predicted for initial martensitic lath width at temperatures below 500 °C. The model is intended for microstructure sensitive design of high temperature materials and components for next generation power plant technology.

Original language	English
Pages (from-to)	286-297
Number of pages	12
Journal	Computational Materials Science
Volume	92
DOIs	https://doi.org/10.1016/j.commatsci.2014.05.034
Publication status	Published - Sep 2014

Keywords

Cyclic softening
Cyclic viscoplasticity
Dislocation density
P91 steel
Precipitate hardening

Authors (Note for portal: view the doc link for the full list of authors)

Authors
Barrett, RA, ODonoghue, PE, Leen, SB

Access to Document

10.1016/j.commatsci.2014.05.034

Cite this

@article{8e4509b2ee194e73b5f0c6af853d55f7,

title = "A dislocation-based model for high temperature cyclic viscoplasticity of 9-12Cr steels",

abstract = "A dislocation-based model for high temperature cyclic viscoplasticity in 9-12Cr steels is presented. This model incorporates (i) cyclic softening via decrease in overall dislocation density, loss of low angle boundary dislocations and coarsening of the microstructure and (ii) kinematic hardening via precipitate strengthening and dislocation substructure hardening. The effects of the primary micro-structural variables, viz. precipitate radii, dislocation density and martensitic lath width on cyclic viscoplasticity, reveal a size effect of initial precipitate radii and volume fraction, with smaller radii and a higher density of precipitate producing a stronger material. A similar effect is also predicted for initial martensitic lath width at temperatures below 500 °C. The model is intended for microstructure sensitive design of high temperature materials and components for next generation power plant technology.",

keywords = "Cyclic softening, Cyclic viscoplasticity, Dislocation density, P91 steel, Precipitate hardening",

author = "Barrett, \{R. A.\} and O'Donoghue, \{P. E.\} and Leen, \{S. B.\}",

year = "2014",

month = sep,

doi = "10.1016/j.commatsci.2014.05.034",

language = "English",

volume = "92",

pages = "286--297",

journal = "Computational Materials Science",

issn = "0927-0256",

publisher = "Elsevier B.V.",

}

TY - JOUR

T1 - A dislocation-based model for high temperature cyclic viscoplasticity of 9-12Cr steels

AU - Barrett, R. A.

AU - O'Donoghue, P. E.

AU - Leen, S. B.

PY - 2014/9

Y1 - 2014/9

N2 - A dislocation-based model for high temperature cyclic viscoplasticity in 9-12Cr steels is presented. This model incorporates (i) cyclic softening via decrease in overall dislocation density, loss of low angle boundary dislocations and coarsening of the microstructure and (ii) kinematic hardening via precipitate strengthening and dislocation substructure hardening. The effects of the primary micro-structural variables, viz. precipitate radii, dislocation density and martensitic lath width on cyclic viscoplasticity, reveal a size effect of initial precipitate radii and volume fraction, with smaller radii and a higher density of precipitate producing a stronger material. A similar effect is also predicted for initial martensitic lath width at temperatures below 500 °C. The model is intended for microstructure sensitive design of high temperature materials and components for next generation power plant technology.

AB - A dislocation-based model for high temperature cyclic viscoplasticity in 9-12Cr steels is presented. This model incorporates (i) cyclic softening via decrease in overall dislocation density, loss of low angle boundary dislocations and coarsening of the microstructure and (ii) kinematic hardening via precipitate strengthening and dislocation substructure hardening. The effects of the primary micro-structural variables, viz. precipitate radii, dislocation density and martensitic lath width on cyclic viscoplasticity, reveal a size effect of initial precipitate radii and volume fraction, with smaller radii and a higher density of precipitate producing a stronger material. A similar effect is also predicted for initial martensitic lath width at temperatures below 500 °C. The model is intended for microstructure sensitive design of high temperature materials and components for next generation power plant technology.

KW - Cyclic softening

KW - Cyclic viscoplasticity

KW - Dislocation density

KW - P91 steel

KW - Precipitate hardening

UR - http://www.scopus.com/inward/record.url?scp=84903216211&partnerID=8YFLogxK

U2 - 10.1016/j.commatsci.2014.05.034

DO - 10.1016/j.commatsci.2014.05.034

M3 - Article

SN - 0927-0256

VL - 92

SP - 286

EP - 297

JO - Computational Materials Science

JF - Computational Materials Science

ER -

A dislocation-based model for high temperature cyclic viscoplasticity of 9-12Cr steels

Abstract

Keywords

Authors (Note for portal: view the doc link for the full list of authors)

Access to Document

Other files and links

Fingerprint

Cite this