Effect of temperature and time on the precipitation of κ-carbides in Fe–28Mn–10Al–0.8C low-density steels: Aging mechanism and its impact on material properties

Yulin Gao, Min Zhang, Rui Wang, Xinxin Zhang, Zhunli Tan, Xiaoyu Chong

International Journal of Minerals, Metallurgy, and Materials ›› 2024, Vol. 31 ›› Issue (10) : 2189-2198. DOI: 10.1007/s12613-024-2857-0
Research Article

Effect of temperature and time on the precipitation of κ-carbides in Fe–28Mn–10Al–0.8C low-density steels: Aging mechanism and its impact on material properties

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Abstract

In low-density steel, κ-carbides primarily precipitate in the form of nanoscale particles within austenite grains. However, their precipitation within ferrite matrix grains has not been comprehensively explored, and the second-phase evolution mechanism during aging remains unclear. In this study, the crystallographic characteristics and morphological evolution of κ-carbides in Fe–28Mn–10Al–0.8C (wt%) low-density steel at different aging temperatures and times and the impacts of these changes on the steels’ microhardness and properties were comprehensively analyzed. Under different heat treatment conditions, intragranular κ-carbides exhibited various morphological and crystallographic characteristics, such as acicular, spherical, and short rod-like shapes. At the initial stage of aging, acicular κ-carbides primarily precipitated, accompanied by a few spherical carbides. κ-Carbides grew and coarsened with aging time, the spherical carbides were considerably reduced, and rod-like carbides coarsened. Vickers hardness testing demonstrated that the material’s hardness was affected by the volume fraction, morphology, and size of κ-carbides. Extended aging at higher temperatures led to an increase in carbide size and volume fraction, resulting in a gradual rise in hardness. During deformation, the primary mechanisms for strengthening were dislocation strengthening and second-phase strengthening. Based on these findings, potential strategies for improving material strength are proposed.

Keywords

low-density steel / κ-carbide / solution–aging treatment / hardness

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Yulin Gao, Min Zhang, Rui Wang, Xinxin Zhang, Zhunli Tan, Xiaoyu Chong. Effect of temperature and time on the precipitation of κ-carbides in Fe–28Mn–10Al–0.8C low-density steels: Aging mechanism and its impact on material properties. International Journal of Minerals, Metallurgy, and Materials, 2024, 31(10): 2189‒2198 https://doi.org/10.1007/s12613-024-2857-0

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