Influence of martensite and grain size on the mechanical behavior of austenitic Fe–C–Mn–Ni–Al medium Mn steels with TWIP mechanism under uniaxial tension/compression and micromechanical creep

Influence of martensite and grain size on the mechanical behavior of austenitic Fe–C–Mn–Ni–Al medium Mn steels with TWIP mechanism under uniaxial tension/compression and micromechanical creep

Medium Mn steels with induced plasticity mechanisms have effectively addressed the high-strength and ductility requirements for structural applications. However, there is still uncertainty about the impact of residual martensite on medium Mn steels with an austenitic matrix under uniaxial tension an...

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Bibliographic Details
Published in:Materials chemistry and physics Vol. 328; p. 129966
Main Authors: Oñate, Angelo, Castro, Martin, Medina, Carlos, Sanhueza, Juan Pablo, Tuninetti, Víctor, Meléndrez, Manuel, Rojas, David
Format: Journal Article
Language:English
Published: Elsevier B.V 01-12-2024
Subjects:
Austenitic steel
Martensite
Medium Mn steel
Nanoindentation
Twinning
Twinning
Martensite
Medium Mn steel
Austenitic steel
Nanoindentation
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Summary:Medium Mn steels with induced plasticity mechanisms have effectively addressed the high-strength and ductility requirements for structural applications. However, there is still uncertainty about the impact of residual martensite on medium Mn steels with an austenitic matrix under uniaxial tension and compression. Furthermore, research on the influence of grain size through incomplete recrystallization in medium Mn alloys is scarce. In this context, our study focused on design and manufacturing a medium Mn Fe–C–Mn–Ni–Al alloy through controlled atmosphere casting incorporating martensite, aiming to analyze its effects under uniaxial stress conditions. Thermomechanical and annealing heat treatments were applied to control grain growth and nucleation of new grains, allowing us to explore how grain size affects the twinning process and mechanical reinforcement in the alloy. Microstructural characterization techniques, including optical and scanning electron microscopy, were employed to assess the mechanical response and damage mechanisms. Mechanical tests included tension, compression, and nanoindentation. The results indicated that residual martensite generates an accelerated damage mechanism under tension due to co-deformation at the interface with austenite, resulting in crack nucleation and rapid propagation through mode I fracture. Consequently, ductility in tension significantly decreases, while no apparent failure is observed during the compression deformation process. Furthermore, incomplete recrystallization was observed to enhance the creep response in both tension and compression. The strain hardening rate results revealed the activation of primary twinning in tension and both primary and secondary twinning in compression for annealed samples. Nanoindentation tests confirmed the presence of twinning and revealed that diffusion creep and grain boundary sliding are the predominant creep mechanisms. •Ferrite/martensite phase in medium Mn steel promotes cracking under tensile stress.•Small grain sizes significantly reduce strain hardening rate under compression stress.•Nanoindentation reveals that crack nucleation occurs through a co-deformation process.
ISSN:0254-0584
DOI:10.1016/j.matchemphys.2024.129966