Microstructural design for damage tolerance in high strength steels

[Display omitted] •Evolutions of damage in 1G and 3G steels are quantified using X-ray tomography.•Grain refinement is found to increase damage tolerance in the steels.•Transformation induced plasticity significantly increases damage tolerance.•Influences of Grain refinement and TRIP are reported on...

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Published inMaterials letters Vol. 269; p. 127664
Main Authors Samei, Javad, Pelligra, Concetta, Amirmaleki, M., Wilkinson, David S.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 15.06.2020
Elsevier BV
Subjects
Computed tomography
Damage tolerance
Deformation and fracture
Grain refinement
High strength steels
Martensite
Materials science
Retained austenite
Tensile tests
Third-generation steels
Transformation induced plasticity
X-ray techniques
Deformation and fracture
X-ray techniques
Grain refinement
Transformation induced plasticity
Third-generation steels
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Abstract [Display omitted] •Evolutions of damage in 1G and 3G steels are quantified using X-ray tomography.•Grain refinement is found to increase damage tolerance in the steels.•Transformation induced plasticity significantly increases damage tolerance.•Influences of Grain refinement and TRIP are reported on RT model coefficients.•Grain refinement and TRIP are recommended for microstructural design of 3G steels. We have investigated the capabilities of first and third-generation high strength steels for sustainable accommodation of microstructural damage before fracture occurs. Steels have been subjected to tensile tests followed by X-ray computed tomography to record the evolution of microstructural damage during deformation. Damage growth is correlated with the Rice-Tracey model. Results show that both grain refinement and transformation induced plasticity of retained austenite to martensite lead to enhanced damage tolerance, leading to the suppression of fracture and improved ductility.
AbstractList We have investigated the capabilities of first and third-generation high strength steels for sustainable accommodation of microstructural damage before fracture occurs. Steels have been subjected to tensile tests followed by X-ray computed tomography to record the evolution of microstructural damage during deformation. Damage growth is correlated with the Rice-Tracey model. Results show that both grain refinement and transformation induced plasticity of retained austenite to martensite lead to enhanced damage tolerance, leading to the suppression of fracture and improved ductility.
[Display omitted] •Evolutions of damage in 1G and 3G steels are quantified using X-ray tomography.•Grain refinement is found to increase damage tolerance in the steels.•Transformation induced plasticity significantly increases damage tolerance.•Influences of Grain refinement and TRIP are reported on RT model coefficients.•Grain refinement and TRIP are recommended for microstructural design of 3G steels. We have investigated the capabilities of first and third-generation high strength steels for sustainable accommodation of microstructural damage before fracture occurs. Steels have been subjected to tensile tests followed by X-ray computed tomography to record the evolution of microstructural damage during deformation. Damage growth is correlated with the Rice-Tracey model. Results show that both grain refinement and transformation induced plasticity of retained austenite to martensite lead to enhanced damage tolerance, leading to the suppression of fracture and improved ductility.
ArticleNumber 127664
Author Wilkinson, David S.
Pelligra, Concetta
Samei, Javad
Amirmaleki, M.
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  givenname: David S.
  surname: Wilkinson
  fullname: Wilkinson, David S.
  organization: Department of Materials Science and Engineering, McMaster University, Hamilton, Canada
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Keywords Deformation and fracture
X-ray techniques
Grain refinement
Transformation induced plasticity
Third-generation steels
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Snippet [Display omitted] •Evolutions of damage in 1G and 3G steels are quantified using X-ray tomography.•Grain refinement is found to increase damage tolerance in...
We have investigated the capabilities of first and third-generation high strength steels for sustainable accommodation of microstructural damage before...
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StartPage 127664
SubjectTerms Computed tomography
Damage tolerance
Deformation and fracture
Grain refinement
High strength steels
Martensite
Materials science
Retained austenite
Tensile tests
Third-generation steels
Transformation induced plasticity
X-ray techniques
Title Microstructural design for damage tolerance in high strength steels
URI https://dx.doi.org/10.1016/j.matlet.2020.127664
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