Effects of heating temperature and atmosphere on element distribution and microstructure in high-Mn/Al austenitic low-density steel

Qi Zhang , Guanghui Chen , Yuemeng Zhu , Zhengliang Xue , Guang Xu

International Journal of Minerals, Metallurgy, and Materials ›› 2024, Vol. 31 ›› Issue (12) : 2670 -2680.

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International Journal of Minerals, Metallurgy, and Materials ›› 2024, Vol. 31 ›› Issue (12) :2670 -2680. DOI: 10.1007/s12613-024-2867-y
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Effects of heating temperature and atmosphere on element distribution and microstructure in high-Mn/Al austenitic low-density steel
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Abstract

The elemental distribution and microstructure near the surface of high-Mn/Al austenitic low-density steel were investigated after isothermal holding at temperatures of 900–1200°C in different atmospheres, including air, N2, and N2 + CO2. No ferrite was formed near the surface of the experimental steel during isothermal holding at 900 and 1000°C in air, while ferrite was formed near the steel surface at holding temperatures of 1100 and 1200°C. The ferrite fraction was larger at 1200°C because more C and Mn diffused to the surface, exuded from the steel, and then reacted with N and O to form oxidation products. The thickness of the compound scale increased owing to the higher diffusion rate at higher temperatures. In addition, after isothermal holding at 1100°C in N2, the Al content near the surface slightly decreased, while the C and Mn contents did not change. Therefore, no ferrite was formed near the surface. However, the near-surface C and Al contents decreased after holding at 1100°C in the N2 + CO2 mixed atmosphere, resulting in the formation of a small amount of ferrite. The compound scale was thickest in N2, followed by the N2 + CO2 mixed atmosphere, and thinnest in air. Overall, the element loss and ferrite fraction were largest after holding in air at the same temperature. The differences in element loss and ferrite fraction between in N2 and N2 + CO2 atmospheres were small, but the compound scale formed in N2 was significantly thicker. According to these results, N2 + CO2 is the ideal heating atmosphere for the industrial production of high-Mn/Al austenitic low-density steel.

Keywords

low-density steel / oxidation / microstructure / element distribution / compound scale

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Qi Zhang, Guanghui Chen, Yuemeng Zhu, Zhengliang Xue, Guang Xu. Effects of heating temperature and atmosphere on element distribution and microstructure in high-Mn/Al austenitic low-density steel. International Journal of Minerals, Metallurgy, and Materials, 2024, 31(12): 2670-2680 DOI:10.1007/s12613-024-2867-y

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

S.F. Hu, Z.B. Zheng, W.P. Yang, and H.K. Yang, Fe–Mn–C–Al low-density steel for structural materials: A review of alloying, heat treatment, microstructure, and mechanical properties, Steel Res. Int., 93(2022), No. 9, art. No. 2200191.
[2]

H. Ding, D.G. Liu, M.H. Cai, and Y. Zhang, Austenite-based Fe–Mn–Al–C lightweight steels: Research and prospective, Metals, 12(2022), No. 10, art. No. 1572.
[3]

Tang CM, Guo ZQ, Pan J, et al. . Current situation of carbon emissions and countermeasures in China’s ironmaking industry. Int. J. Miner. Metall. Mater.. 2023, 30(9): 1633

[4]

Lu X, Tian WJ, Li H, Li XJ, Quan K, Bai H. Decarbonization options of the iron and steelmaking industry based on a three-dimensional analysis. Int. J. Miner. Metall. Mater.. 2023, 30(2): 388

[5]

Gutierrez-Urrutia I. Low density Fe–Mn–Al–C steels: Phase structures, mechanisms and properties. ISIJ Int.. 2021, 61(1): 16

[6]

Chen SP, Rana R, Haldar A, Ray RK. Current state of Fe–Mn–Al–C low density steels. Prog. Mater. Sci.. 2017, 89: 345

[7]

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

[8]

Ramos-Fabián NI, Mejía I, García-Domínguez M, Bedolla-Jacuinde A. Metallographic, structural and mechanical characterization of a low-density austenitic Fe–Mn–Al–C steel microalloyed with Nb in hot-rolling condition. MRS Adv.. 2023, 8(22): 1291

[9]

Y.X. Liu, M.X. Liu, J.L. Zhang, et al., Microstructure and mechanical properties of a Fe–28Mn–9Al–1.2C–(0, 3, 6, 9)Cr austenitic low-density steel, Mater. Sci. Eng. A, 821(2021), art. No. 141583.
[10]

Park KT, Hwang SW, Son CY, Lee JK. Effects of heat treatment on microstructure and tensile properties of a Fe–27Mn–12Al–0.8C low-density steel. JOM. 2014, 66(9): 1828

[11]

Li S, Yang ZN, Zurob HS, Chen H, Zhang C, Yang ZG. On the decarburization of surface pearlite. Metall. Mater. Trans. A. 2021, 52(8): 3198

[12]

Wild RK. Vacuum annealing of stainless steel at temperatures between 770 and 1470K. Corros. Sci.. 1974, 14(10): 575

[13]

Q. Zhang, G.H. Chen, Y.P. Shen, Z.L. Xue, and G. Xu, Micro-structure evolution on the surface of Fe–20Mn–6Al–0.6C–0.15Si austenitic low-density steel during heat treatment, J. Mater. Eng. Perform., (2023). DOI: https://doi.org/10.1007/s11665-023-08803-7
[14]

Zhou MX, Wang HX, Zhu M, et al. . New insights to the metallurgical mechanism of niobium in high-carbon pearlitic steels. J. Mater. Res. Technol.. 2023, 26: 1609

[15]

Alvarenga HD, van de Putte T, van Steenberge N, Sietsma J, Terryn H. Influence of carbide morphology and microstructure on the kinetics of superficial decarburization of C–Mn steels. Metall. Mater. Trans. A. 2015, 46(1): 123

[16]

Guo Y, Dai FQ, Hu ST, Xu G. Effect of surface oxidation on decarburization of a Fe–3%Si steel during annealing. ISIJ Int.. 2018, 58(9): 1727

[17]

Hajduga M, Kučera J. Decarburization of Fe–Cr–C steels during high-temperature oxidation. Oxid. Met.. 1988, 29(5): 419

[18]

X.N. Duan, H. Yu, J. Lu, and Z. Huang, Temperature dependence and formation mechanism of surface decarburization behavior in 35CrMo steel, Steel Res. Int., 90(2019), No. 9, art. No. 1900188.
[19]

Gildersleeve MJ. Relationship between decarburisation and fatigue strength of through hardened and carburising steels. Mater. Sci. Technol.. 1991, 7(4): 307

[20]

Carroll RI, Beynon JH. Decarburisation and rolling contact fatigue of a rail steel. Wear. 2006, 260(4–5): 523

[21]

Rafiei A, Irons GA, Coley KS. Argon-oxygen decarburization of high manganese steels: Effect of temperature, alloy composition, and submergence depth. Metall. Mater. Trans. B. 2021, 52(4): 2509

[22]

Chen YR, Xu XX, Liu Y. Decarburization of 60Si2MnA in atmospheres containing different levels of oxygen, water vapour and carbon dioxide at 700–1000°C. Oxid. Met.. 2020, 93(1): 105

[23]

Liu YB, Zhang W, Tong Q, Sun QS. Effects of Si and Cr on complete decarburization behavior of high carbon steels in atmosphere of 2 vol.% O2. J. Iron Steel Res. Int.. 2016, 23(12): 1316

[24]

Nomura M, Morimoto H, Toyama M. Calculation of ferrite decarburizing depth, considering chemical composition of steel and heating condition. ISIJ Int.. 2000, 40(6): 619

[25]

Chu JH, Bao YP. Mn evaporation and denitrification behaviors of molten Mn steel in the vacuum refining with slag process. Int. J. Miner. Metall. Mater.. 2021, 28(8): 1288

[26]

J.H. Chu and Y.P. Bao, Volatilization behavior of manganese from molten steel with different alloying methods in vacuum, Metals, 10(2020), No. 10, art. No. 1348.
[27]

Lan FJ, Zhuang CL, Li CR, Chen JB, Yang GK, Yao HJ. Study on manganese volatilization behavior of Fe–Mn–C–Al twinning-induced plasticity steel. High Temp. Mater. Process.. 2021, 40(1): 461

[28]

Smitll AF, Hales R. Diffusion of manganese in type 316 austenitic stainless steel. Met. Sci.. 1975, 9(1): 181

[29]

Catteau SD, Sourmail T, Moine A. Dilatometric study of phase transformations in steels: Some issues. Mater. Perform. Charact.. 2016, 5(5): 564

[30]

Kumar S, Mahobia GS. Cyclic oxidation of Fe–18Cr–21Mn–0.65N austenitic stainless steel at 400–700°C. Trans. Indian Inst. Met.. 2020, 73(10): 2457

[31]

Y. Guo, J.H. Zhao, B. Xu, C. Gu, K.Q. Feng, and Y.J. Wang, Effect of high-temperature oxidation on the subsurface microstructure and magnetic property of medium manganese austenitic steel, J. Alloys Compd., 913(2022), art. No. 165254.
[32]

de Freitas Cunha Lins V, Freitas MA, de Paula E Silva EM. Oxidation kinetics of an Fe–31.8Mn–6.09Al–1.60Si–0.40C alloy at temperatures from 600 to 900°C. Corros. Sci.. 2004, 46(8): 1895

[33]

de Sousa Malafaia AM, Latu-Romain L, Wouters Y. High temperature oxidation resistance improvement in an FeMnSiCrNi alloy by Mn-depletion under vacuum annealing. Mater. Lett.. 2019, 241: 164

[34]

G.H. Chen, R. Rahimi, G. Xu, H. Biermann, and J. Mola, Impact of Al addition on deformation behavior of Fe–Cr–Ni–Mn–C austenitic stainless steel, Mater. Sci. Eng. A, 797(2020), art. No. 140084.
[35]

G.H. Chen, G. Xu, H. Biermann, and J. Mola, Microstructure and mechanical properties of Co-added and Al-added austenitic stainless steels, Mater. Sci. Eng. A, 854(2022), art. No. 143832.
[36]

Han P, Liu ZP, Xie ZJ, et al. . Influence of band microstructure on carbide precipitation behavior and toughness of 1 GPa-grade ultra-heavy gauge low-alloy steel. Int. J. Miner. Metall. Mater.. 2023, 30(7): 1329

[37]

A.J. Maldonado, K.P. Misra, and R.D.K. Misra, Grain boundary segregation in a high entropy alloy, Mater. Technol., 38(2023), No. 1, art. No. 2221959.
[38]

Huang ZY, Jiang YS, Hou AL, et al. . Rietveld refinement, microstructure and high-temperature oxidation characteristics of low-density high manganese steels. J. Mater. Sci. Technol.. 2017, 33(12): 1531

[39]

Duh JG, Wang CJ. Formation and growth morphology of oxidation-induced ferrite layer in Fe–Mn–Al–Cr–C alloys. J. Mater. Sci.. 1990, 25(4): 2063

[40]

Yang YL, Yang CH, Lin SN, Chen CH, Tsai WT. Effects of Si and its content on the scale formation on hot-rolled steel strips. Mater. Chem. Phys.. 2008, 112(2): 566

[41]

Park SH, Chung IS, Kim TW. Characterization of the high-temperature oxidation behavior in Fe–25Mn–1.5Al–0.5C alloy. Oxid. Met.. 1998, 49(3): 349

[42]

Jackson PRS, Wallwork GR. High temperature oxidation of iron–manganese–aluminum based alloys. Oxid. Met.. 1984, 21(3): 135

[43]

Yang WS, Wan CM. High temperature studies of Fe–Mn–Al–C alloys with different manganese concentrations in air and nitrogen. J. Mater. Sci.. 1989, 24(10): 3497

[44]

Sun JL, Huang BY, He JQ, Meng EC, Chang QH. Achieving oxidation protection effect for strips hot rolling via Al2O3 nanofluid lubrication. Int. J. Miner. Metall. Mater.. 2023, 30(5): 908

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