Microstructure-mechanical property evaluation and deformation mechanism in Al added medium Mn steel processed through intercritical rolling and annealing

The present work investigates the microstructure evolution, mechanical properties and deformation mechanism in medium Mn high Al steel processed through intercritical rolling and subsequent intercritical annealing treatment at different temperatures. The annealed samples possessed a multi-phase micr...

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Published inMaterials science & engineering. A, Structural materials : properties, microstructure and processing Vol. 799; p. 140100
Main Authors Sahoo, Biraj Kumar, Srivastava, Vikas Chandra, Mahato, B., Ghosh Chowdhury, Sandip
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 02.01.2021
Elsevier BV
Subjects
Aluminum
Annealing
Austenite
Chemical composition
Deformation effects
Deformation mechanisms
Delta ferrite
Ductility
Elongation
Equiaxed structure
Grain size
Grain structure
Intercritical annealing
Intercritical rolling
Low-density steel
Manganese steels
Martensite
Mechanical properties
Medium Mn steel
Microstructure
Morphology
Plastic properties
Stability
Strain hardening
TRIP
TWIP
Ultimate tensile strength
Work hardening
Intercritical annealing
TRIP
Low-density steel
TWIP
Medium Mn steel
Intercritical rolling
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Abstract The present work investigates the microstructure evolution, mechanical properties and deformation mechanism in medium Mn high Al steel processed through intercritical rolling and subsequent intercritical annealing treatment at different temperatures. The annealed samples possessed a multi-phase microstructure consisting of intercritical ferrite/martensite, austenite and δ-ferrite. However, the morphology of the phases varied with annealing temperature. The result shows that annealing at a temperature of 730° and 780 °C led to the development of bimodal grain structure consisting of fine laths and equiaxed ultra-fine-grains (UFG) of ferrite-austenite; whereas annealing at 830 °C led to fully equiaxed coarse ferrite-austenite grains. An excellent combination of strength and ductility (product of ultimate tensile strength and elongation) as high as 56 GPa% was obtained in the 780 °C annealed sample. The chemical composition and grain size of austenite was found to be critical factors governing its stability. A mixture of lath and equiaxed austenite grains, having appropriate stability, in 780 °C annealed sample led to sustained four-stage strain hardening during deformation. Multiple work hardening mechanisms involving transformation induced plasticity (TRIP) effect, twin induced plasticity (TWIP) effect and discontinuous TRIP effect were found to occur sequentially in the equiaxed and lath-type austenite during the deformation that led to the extraordinary strength ductility combination.
AbstractList The present work investigates the microstructure evolution, mechanical properties and deformation mechanism in medium Mn high Al steel processed through intercritical rolling and subsequent intercritical annealing treatment at different temperatures. The annealed samples possessed a multi-phase microstructure consisting of intercritical ferrite/martensite, austenite and δ-ferrite. However, the morphology of the phases varied with annealing temperature. The result shows that annealing at a temperature of 730° and 780 °C led to the development of bimodal grain structure consisting of fine laths and equiaxed ultra-fine-grains (UFG) of ferrite-austenite; whereas annealing at 830 °C led to fully equiaxed coarse ferrite-austenite grains. An excellent combination of strength and ductility (product of ultimate tensile strength and elongation) as high as 56 GPa% was obtained in the 780 °C annealed sample. The chemical composition and grain size of austenite was found to be critical factors governing its stability. A mixture of lath and equiaxed austenite grains, having appropriate stability, in 780 °C annealed sample led to sustained four-stage strain hardening during deformation. Multiple work hardening mechanisms involving transformation induced plasticity (TRIP) effect, twin induced plasticity (TWIP) effect and discontinuous TRIP effect were found to occur sequentially in the equiaxed and lath-type austenite during the deformation that led to the extraordinary strength ductility combination.
The present work investigates the microstructure evolution, mechanical properties and deformation mechanism in medium Mn high Al steel processed through intercritical rolling and subsequent intercritical annealing treatment at different temperatures. The annealed samples possessed a multi-phase microstructure consisting of intercritical ferrite/martensite, austenite and δ-ferrite. However, the morphology of the phases varied with annealing temperature. The result shows that annealing at a temperature of 730° and 780 °C led to the development of bimodal grain structure consisting of fine laths and equiaxed ultra-fine-grains (UFG) of ferrite-austenite; whereas annealing at 830 °C led to fully equiaxed coarse ferrite-austenite grains. An excellent combination of strength and ductility (product of ultimate tensile strength and elongation) as high as 56 GPa% was obtained in the 780 °C annealed sample. The chemical composition and grain size of austenite was found to be critical factors governing its stability. A mixture of lath and equiaxed austenite grains, having appropriate stability, in 780 °C annealed sample led to sustained four-stage strain hardening during deformation. Multiple work hardening mechanisms involving transformation induced plasticity (TRIP) effect, twin induced plasticity (TWIP) effect and discontinuous TRIP effect were found to occur sequentially in the equiaxed and lath-type austenite during the deformation that led to the extraordinary strength ductility combination.
ArticleNumber 140100
Author Sahoo, Biraj Kumar
Ghosh Chowdhury, Sandip
Srivastava, Vikas Chandra
Mahato, B.
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  givenname: Sandip
  surname: Ghosh Chowdhury
  fullname: Ghosh Chowdhury, Sandip
  email: sgc@nmlindia.org
  organization: Academy of Scientific and Innovative Research (AcSIR), Ghaziabad, 201002, India
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TRIP
Low-density steel
TWIP
Medium Mn steel
Intercritical rolling
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Snippet The present work investigates the microstructure evolution, mechanical properties and deformation mechanism in medium Mn high Al steel processed through...
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SubjectTerms Aluminum
Annealing
Austenite
Chemical composition
Deformation effects
Deformation mechanisms
Delta ferrite
Ductility
Elongation
Equiaxed structure
Grain size
Grain structure
Intercritical annealing
Intercritical rolling
Low-density steel
Manganese steels
Martensite
Mechanical properties
Medium Mn steel
Microstructure
Morphology
Plastic properties
Stability
Strain hardening
TRIP
TWIP
Ultimate tensile strength
Work hardening
Title Microstructure-mechanical property evaluation and deformation mechanism in Al added medium Mn steel processed through intercritical rolling and annealing
URI https://dx.doi.org/10.1016/j.msea.2020.140100
https://www.proquest.com/docview/2493860690
Volume 799
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