Mechanical behavior of ultrafine-grained eutectoid steel containing Nano-cementite particles

A eutectoid steel with an ultrafine-grained ferrite (α) + submicron/Nano-cementite particle (θ) structure was formed by combining warm deformation of martensite to a strain of 0.36 at 0.1s−1 at 500°C with subsequent annealing at 500°C for 6h. The characteristics of the microstructure were investigat...

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Bibliographic Details
Published inMaterials science & engineering. A, Structural materials : properties, microstructure and processing Vol. 713; pp. 35 - 42
Main Authors Zheng, Chengsi, Li, Longfei
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 24.01.2018
Elsevier BV
Subjects
Annealing
Cementite
Cements
Deformation
Deformation mechanisms
Dislocations
Eutectoid steel
Ferrite
Ferrites
Hardening rate
Martensite
Mathematical models
Mechanical properties
Microstructure
Nano-cementite particles
Necking
Substructures
True strain
Warm deformation of martensite
Work-hardening
Yield strength
Warm deformation of martensite
Nano-cementite particles
Eutectoid steel
Yield strength
Work-hardening
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Summary:A eutectoid steel with an ultrafine-grained ferrite (α) + submicron/Nano-cementite particle (θ) structure was formed by combining warm deformation of martensite to a strain of 0.36 at 0.1s−1 at 500°C with subsequent annealing at 500°C for 6h. The characteristics of the microstructure were investigated by means of a scanning electronic microscope and transmission electron microscope, and the corresponding mechanical behavior was analyzed in comparison with that of the eutectoid steel with a typical ultrafine-grained α + θ structure. The results show that both ferrite matrix and cementite particles of the ultrafine-grained α + submicron/Nano-θ steel are finer than that of the ultrafine-grained α + θ steel, i.e., the average size of approximately 0.54µm vs. 1.0µm and 0.20µm vs. 0.56µm, accompanying with a continuous yielding and a discontinuous yielding, respectively. The yield strength of the ultrafine-grained α + submicron/Nano-θ steel is 264MPa higher that of the ultrafine-grained α + θ steel, i.e., 884MPa vs. 620MPa, resulting from the enhancement caused by refined ferrite grains and cementite particles. The intragranular cementite particles within the ultrafine-grained α + submicron/Nano-θ steel are in Nano-scale, i.e., an average size of approximately 60nm, resulting in plenty of geometrically necessary dislocations (GNDs) to bring its work-hardening rate higher than that of the ultrafine-grained α + θ steel during uniform deformation. As a result, the stress increments caused by work-hardening are 89MPa and 155MPa for the ultrafine-grained α + θ steel and the ultrafine-grained α + submicron/Nano-θ steel, respectively, and their interval length of uniform strain range are nearly equal, i.e., a true strain of approximately 0.08. The work-hardening rate of the ultrafine-grained α + θ steel decline continuously with the increase of tensile strain during uniform deformation. However, the ultrafine-grained α + submicron/Nano-θ steel shows that the work-hardening rate decrease rapidly at the initial stage of work-hardening and then raise within a small strain range, then following by a slowly continuous decline to necking, and, namely, there has a peak of work-hardening rate. Furthermore, the work-hardening rate curve were divided into three stages, and the work-hardening behavior of Stage I, II and III were discussed in view of the evolution of dislocation substructures and the analytical model based on the Kocks-Mecking model.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2017.12.051