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C-modified stacking-fault networks inducing the excellent strength- plasticity combinations of medium manganese steel by simple two-stage warm rolling without annealing

Yingchao Zhang, Renbo Song, Yongjin Wang, Changhong Cai, Haibo Wang, Kaikun Wang

2023Scripta Materialia24 citationsDOIOpen Access PDF

Abstract

The medium manganese steel with ultrahigh yield strength of 1421 MPa, a tensile strength of 1575 MPa, and an excellent total elongation of 28.4% was designed by simple two-stage warm rolling without annealing. The improvement of yield strength is mainly attributed to the extensive strengthening defects in the lamellar dual-phase microstructures, which including the high-density dislocations in ferrites and high-density dislocations, nanoscale VC precipitates, stacking faults and Lomer-Cottrell (L-C) locks in austenite (22 Vol.%). In addition, the abnormally enhanced strain-hardening ability benefits from the C-modified stacking-fault networks, whose stability and C-segregated characteristics are precisely clarified by the advanced in-situ heating HRTEM and APT analysis. This special strengthening and plasticizing effects of stacking faults induced by simple two-stage warm rolling can effectively break through the trade-off between strength and plasticity of ultra-strong medium manganese steel .

Topics & Concepts

Materials scienceAnnealing (glass)Ultimate tensile strengthManganeseAusteniteStackingPlasticityMicrostructureLamellar structureStacking faultElongationComposite materialHigh-resolution transmission electron microscopyHardening (computing)Stacking-fault energyMetallurgyDislocationNanotechnologyTransmission electron microscopyPhysicsNuclear magnetic resonanceLayer (electronics)Microstructure and Mechanical Properties of SteelsMetal Alloys Wear and PropertiesMetal and Thin Film Mechanics