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.

International Journal of Minerals, Metallurgy, and Materials All Journals
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

Author information +
History +

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

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾
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
This is a preview of subscription content, contact us for subscripton.

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]
Lu HT, Li DZ, Li SY, Chen YA. Hot deformation behavior of Fe–27.34Mn–8.63Al–1.03C lightweight steel. Int. J. Miner. Metall. Mater., 2023, 30(4): 734,
CrossRef Google scholar
[2]
Xie LZ, Xu ZG, Qi YZ, Liang JR, He P, Shen Q, Wang CB. Effect of ball milling time on the microstructure and compressive properties of the Fe–Mn–Al porous steel. Int. J. Miner. Metall. Mater., 2023, 30(5): 917,
CrossRef Google scholar
[3]
Huang ZY, Hou AL, Jiang YS, et al.. Rietveld refinement, microstructure, mechanical properties and oxidation characteristics of Fe–28Mn–xAl–1C (x = 10 and 12 wt. %) low-density steels. J. Iron Steel Res. Int., 2017, 24(12): 1190,
CrossRef Google scholar
[4]
L.L. Wei, G.H. Gao, J. Kim, R.D.K. Misra, C.G. Yang, and X.J. Jin, Ultrahigh strength-high ductility 1GPa low density austenitic steel with ordered precipitation strengthening phase and dynamic slip band refinement, Mater. Sci. Eng. A, 838(2022), art. No. 142829.
[5]
D.G. Liu, H. Ding, D. Han, and M.H. Cai, Effect of grain interior and grain boundary κ-carbides on the strain hardening behavior of medium-Mn lightweight steels, Mater. Sci. Eng. A, 871(2023), art. No. 144861.
[6]
P. Ren, X.P. Chen, L. Mei, Y.Y. Nie, W.Q. Cao, and Q. Liu, Intragranular brittle precipitates improve strain hardening capability of Fe–30Mn–11Al–1.2C low-density steel, Mater. Sci. Eng. A, 775(2020), art. No. 138984.
[7]
Chen SP, Rana R, Haldar A, Ray RK. Current state of Fe–Mn–Al–C low density steels. Prog. Mater. Sci., 2017, 89: 345,
CrossRef Google scholar
[8]
Zhang Y, Zhang ZZ, Medhekar NV, Bourgeois L. Vacancy-tuned precipitation pathways in Al–1.7Cu–0.025In–0.025Sb (at.%) alloy. Acta Mater., 2017, 141: 341,
CrossRef Google scholar
[9]
Jin JE, Lee YK. Effects of Al on microstructure and tensile properties of C-bearing high Mn TWIP steel. Acta Mater., 2012, 60(4): 1680,
CrossRef Google scholar
[10]
Park KT, Jin KG, Han SH, Hwang SW, Choi K, Lee CS. Stacking fault energy and plastic deformation of fully austenitic high manganese steels: Effect of Al addition. Mater. Sci. Eng. A, 2010, 527(16–17): 3651,
CrossRef Google scholar
[11]
Jeong JS, Woo W, Oh KH, Kwon SK, Koo YM. In situ neutron diffraction study of the microstructure and tensile deformation behavior in Al-added high manganese austenitic steels. Acta Mater., 2012, 60(5): 2290,
CrossRef Google scholar
[12]
Yao MJ, Welsch E, Ponge D, et al.. Strengthening and strain hardening mechanisms in a precipitation-hardened high-Mn lightweight steel. Acta Mater., 2017, 140: 258,
CrossRef Google scholar
[13]
A. Banis, A. Gomez, A. Dutta, I. Sabirov, and R.H. Petrov, The effect of nano-sized κ-carbides on the mechanical properties of an Fe–Mn–Al–C alloy, Mater. Charact., 205(2023), art. No. 113364.
[14]
P. Chen, Q.C. Zhang, F. Zhang, J.H. Du, F. Shi, and X.W. Li, Critical role of κ-carbides in the multi-stage work hardening process of a lightweight austenitic steel, Mater. Charact., 200(2023), art. No. 112853.
[15]
P. Dey, R. Nazarov, B. Dutta, et al., Ab initio explanation of disorder and off-stoichiometry in Fe–Mn–Al–C κ carbides, Phys. Rev. B, 95(2017), No. 10, art. No. 104108.
[16]
C. Kim, H.U. Hong, J.H. Jang, et al., Reverse partitioning of Al from κ-carbide to the γ-matrix upon Ni addition and its strengthening effect in Fe–Mn–Al–C lightweight steel, Mater. Sci. Eng. A, 820(2021), art. No. 141563.
[17]
Choi K, Seo CH, Lee H, et al.. Effect of aging on the microstructure and deformation behavior of austenite base light-weight Fe–28Mn–9Al–0.8C steel. Scr. Mater., 2010, 63(10): 1028,
CrossRef Google scholar
[18]
J. Wang, M.X. Yang, X.L. Wu, and F.P. Yuan, Achieving better synergy of strength and ductility by adjusting size and volume fraction of coherent κ’–carbides in a lightweight steel, Mater. Sci. Eng. A, 857(2022), art. No. 144085.
[19]
Gutierrez-Urrutia I, Raabe D. Influence of Al content and precipitation state on the mechanical behavior of austenitic high-Mn low-density steels. Scripta Mater., 2013, 68(6): 343,
CrossRef Google scholar
[20]
Lin CL, Chao CG, Bor HY, Liu TF. Relationship between microstructures and tensile properties of an Fe–30Mn–8.5Al–2.0C alloy. Mater. Trans., 2010, 51(6): 1084,
CrossRef Google scholar
[21]
Zhang JL, Raabe D, Tasan CC. Designing duplex, ultrafine-grained Fe–Mn–Al–C steels by tuning phase transformation and recrystallization kinetics. Acta Mater., 2017, 141: 374,
CrossRef Google scholar
[22]
H. Wang, C.Y. Wang, J.X. Liang, et al., Effect of alloying content on microstructure and mechanical properties of Fe–Mn–Al–C low-density steels, Mater. Sci. Eng. A, 886(2023), art. No. 145675.
[23]
Park SW, Park JY, Cho KM, et al.. Effect of Mn and C on age hardening of Fe–Mn–Al–C lightweight steels. Met. Mater. Int., 2019, 25(3): 683,
CrossRef Google scholar
[24]
Chao CY, Hwang CN, Liu TF. Grain boundary precipitation in an Fe–7.8Al–31.7Mn–0.54C alloy. Scripta Metall. Mater., 1993, 28(1): 109,
CrossRef Google scholar
[25]
Chao CY, Hwang CN, Liu TF. Grain boundary precipitation behaviors in an Fe–9.8Al–28.6Mn–0.8Si–1.0C alloy. Scripta Mater., 1996, 34(1): 75,
CrossRef Google scholar
[26]
Li MC, Chang H, Kao PW, Gan D. The effect of Mn and Al contents on the solvus of κ phase in austenitic Fe–Mn–Al–C alloys. Mater. Chem. Phys., 1999, 59(1): 96,
CrossRef Google scholar
[27]
Feng YF, Song RB, Pei ZZ, Song RF, Dou GY. Effect of aging isothermal time on the microstructure and room-temperature impact toughness of Fe–24.8Mn–7.3Al–1.2C austenitic steel with κ-carbides precipitation. Met. Mater. Int., 2018, 24(5): 1012,
CrossRef Google scholar
[28]
T.H. Zhang, H.Y. Wei, K. Zhang, et al., Effect of cooling medium on the κ carbide precipitation behavior, microstructure and impact properties of FeMnAlC low-density steel, Mater. Today Commun., 37(2023), art. No. 107084.
[29]
Xiao L, Zhou YJ, Zhang CH, Wang YY, Deng XT, Wang ZD. Improving impact toughness of Fe–20Mn–9Al–1.5C–2Ni–3Cr low-density steel by optimizing grain boundaries via multi-stage heat treatment without compromising high strength and ductility. J. Mater. Res. Technol., 2024, 29: 2396,
CrossRef Google scholar
[30]
Jeong J, Lee CY, Park IJ, Lee YK. Isothermal precipitation behavior of κ-carbide in the Fe–9Mn–6Al–0.15C light-weight steel with a multiphase microstructure. J. Alloys Compd., 2013, 574: 299,
CrossRef Google scholar
[31]
Cheng WC. Phase transformations of an Fe–0.85 C–17.9 Mn–7.1 Al austenitic steel after quenching and annealing. JOM, 2014, 66(9): 1809,
CrossRef Google scholar
[32]
Y.F. An, X.P. Chen, P. Ren, and W.Q. Cao, Ultrastrong and ductile austenitic lightweight steel via ultra-fine grains and heterogeneous B2 precipitates, Mater. Sci. Eng. A, 860(2022), art. No. 144330.
[33]
Zambrano OA, Valdés J, Rodriguez LA, et al.. Elucidating the role of κ-carbides in Fe–Mn–Al–C alloys on abrasion wear. Tribol. Int., 2019, 135: 421,
CrossRef Google scholar
[34]
J.L. Zhang, Y.S. Jiang, W.S. Zheng, et al., Revisiting the formation mechanism of intragranular κ-carbide in austenite of a Fe–Mn–Al–Cr–C low-density steel, Scripta Mater., 199(2021), art. No. 113836.
[35]
Kamikawa N, Sato K, Miyamoto G, et al.. Stress–strain behavior of ferrite and bainite with nano-precipitation in low carbon steels. Acta Mater., 2015, 83: 383,
CrossRef Google scholar
[36]
Welsch E, Ponge D, Hafez Haghighat SM, et al.. Strain hardening by dynamic slip band refinement in a high-Mn light-weight steel. Acta Mater., 2016, 116: 188,
CrossRef Google scholar
[37]
Canadinc D, Sehitoglu H, Maier HJ. The role of dense dislocation walls on the deformation response of aluminum alloyed Hadfield steel polycrystals. Mater. Sci. Eng. A, 2007, 454–455: 662,
CrossRef Google scholar

58

Accesses

0

Citations

Detail
Sections
Recommended

/