Recent progress in third-generation low alloy steels developed under M3 microstructure control

Zhen-jia Xie; Cheng-jia Shang; Xue-lin Wang; Xue-min Wang; Gang Han; Raja-devesh-kumar Misra

doi:10.1007/s12613-019-1939-x

International Journal of Minerals, Metallurgy, and Materials ›› 2020, Vol. 27 ›› Issue (1) : 1 -9. DOI: 10.1007/s12613-019-1939-x

Invited Review

Recent progress in third-generation low alloy steels developed under M³ microstructure control

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Abstract

During the past thirty years, two generations of low alloy steels (ferrite/pearlite followed by bainite/martensite) have been developed and widely used in structural applications. The third-generation of low alloy steels is expected to achieve high strength and improved ductility and toughness, while satisfying the new demands for weight reduction, greenness, and safety. This paper reviews recent progress in the development of third-generation low alloy steels with an M³ microstructure, namely, microstructures with multi-phase, meta-stable austenite, and multi-scale precipitates. The review summarizes the alloy designs and processing routes of microstructure control, and the mechanical properties of the alloys. The stabilization of retained austenite in low alloy steels is especially emphasized. Multi-scale nano-precipitates, including carbides of microal-loying elements and Cu-rich precipitates obtained in third-generation low alloy steels, are then introduced. The structure–property relationships of third-generation alloys are also discussed. Finally, the promises and challenges to future applications are explored.

Keywords

third-generation low alloy steels / multi-phase microstructure / meta-stable retained austenite / multi-scale precipitates

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Zhen-jia Xie, Cheng-jia Shang, Xue-lin Wang, Xue-min Wang, Gang Han, Raja-devesh-kumar Misra. Recent progress in third-generation low alloy steels developed under M³ microstructure control. International Journal of Minerals, Metallurgy, and Materials, 2020, 27(1): 1-9 DOI:10.1007/s12613-019-1939-x

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References

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[1]	Fan HL, Zhao AM, Li QC, Guo H, He JG. Effects of ausforming strain on bainite transformation in nanostructured bainite steel. Int. J. Miner. Metall. Mater., 2017, 24, 264.

[2]	B. Avishan, Effect of prolonged isothermal heat treatment on the mechanical behavior of advanced NANOBAIN steel, Int. J. Miner. Metall. Mater, 24 (2017), No. 9, p. 1010.

[3]	Hashemi SG, Eghbali B. Analysis of the formation conditions and characteristics of interphase and random vanadium precipitation in a low-carbon steel during isothermal heat treatment. Int. J. Miner. Metall. Mater, 2018, 25, 339.

[4]	D.L. Li, G.Q. Fu, M.Y. Zhu, Q. Li, and C.X. Yin, Effect of Ni on the corrosion resistance of bridge steel in a simulated hot and humid coastal-industrial atmosphere, Int. J. Miner. Metall. Mater, 25(2018), No. 3, p. 325.

[5]	Shahriari B, Vafaei R, Sharifi EM, Farmanesh K. Aging behavior of a copper-bearing high-strength low-carbon steel. Int. J. Miner. Metall. Mater, 2018, 25, 429.

[6]	Weng YQ, Shang CJ, Yan CF. State-of-the-art and development trends of HSLA steels in China. Iron Steel, 2011, 46, 1.

[7]	Dong H, Wang MQ, Weng YQ. Performance improvement of steels through M³ structure control. Iron Steel, 2010, 45, 1.

[8]	Shen YF, Liu YD, Sun X, Wang YD, Zuo L, Misra RDK. Improved ductility of a transformation-induced-plasticity steel by nanoscale austenite lamellae. Mater. Sci. Eng. A, 2013, 583, 1.

[9]	P.J. Jacques, Transformation-induced plasticity for high strength formable steels, Curr Opin. Solid State Mater. Sci., 8(2004), No. 3–4, p. 259.

[10]	Speer JG, Edmonds DV, Rizzo FC, Matlock DK. Partitioning of carbon from supersaturated plates of ferrite, with application to steel processing and fundamentals of the bainite transformation. Curr. Opin. Solid State. Mater. Sci, 2004, 8, 3-4.

[11]	Speer J, Matlock DK, De Cooman BC, Schroth JG. Carbon partitioning into austenite after martensite transformation. Acta Mater., 2003, 51, 2611.

[12]	Miller RL. Ultrafine-grained microstructures and mechanical properties of alloy steels. Metall. Mater. Trans. B, 1972, 3, 905.

[13]	Luo HW, Shi J, Wang C, Cao WQ, Sun XJ, Dong H. Experimental and numerical analysis on formation of stable austenite during the intercritical annealing of 5Mn steel. Acta Mater., 2011, 59, 4002.

[14]	Misra RDK, Challa VSA, Venkatsurya PKC, Shen YF, Somani MC, Karjalainen LP. Interplay between grain structure, deformation mechanisms and austenite stability in phase-reversion-induced nanograined/ul-trafine-grained austenitic ferrous alloy. Acta Mater, 2015, 84, 339.

[15]	Lee T, Koyama M, Tsuzaki K, Lee YH, Lee CS. Tensile deformation behavior of Fe-Mn-C TWIP steel with ultrafine elongated grain structure. Mater. Lett., 2012, 75, 169.

[16]	Zhou WH, Wang XL, Venkatsurya PKC, Guo H, Shang CJ, Misra RDK. Structure-mechanical property relationship in a high strength low carbon alloy steel processed by two-step intercritical annealing and intercritical tempering. Mater. Sci. Eng. A, 2014, 607, 569.

[17]	Zhou WH, Guo H, Xie ZJ, Wang XM, Shang CJ. High strength low-carbon alloyed steel with good ductility by combining the retained austenite and nano-sized precipitates. Mater. Sci. Eng. A, 2013, 587, 365.

[18]	Zhou WH, Guo H, Xie ZJ, Shang CJ, Misra RDK. Copper precipitation and its impact on mechanical properties in a low carbon microalloyed steel processed by a three-step heat treatment. Mater. Des., 2014, 63, 42.

[19]	Xie ZJ, Yuan SF, Zhou WH, Yang JR, Guo H, Shang CJ. Stabilization of retained austenite by the two-step intercritical heat treatment and its effect on the toughness of a low alloyed steel. Mater. Des., 2014, 59, 193.

[20]	Xie ZJ, Xiong L, Han G, Wang XL, Shang CJ. Thermal stability of retained austenite and properties of a multi-phase low alloy steel. Metals, 2018, 8, 807.

[21]	Xie ZJ, Han G, Zhou WH, Zeng CY, Shang CJ. Study of retained austenite and nano-scale precipitation and their effects on properties of a low alloyed multi-phase steel by the two-step intercritical treatment. Mater. Charact, 2016, 113, 60.

[22]	Han G, Xie ZJ, Xiong L, Shang CJ, Msra RDK. Evolution of nano-size precipitation and mechanical properties in a high strength-ductility low alloy steel through intercritical treatment. Mater. Sci. Eng. A, 2017, 705, 89.

[23]	Han G, Xie ZJ, Lei B, Liu WQ, Zhu HH, Yan Y, Misra RDK, Shang CJ. Simultaneous enhancement of strength and plasticity by nano B2 clusters and nano-γ phase in a low carbon low alloy steel. Mater. Sci. Eng. A, 2018, 730, 119.

[24]	Nie WJ, Wang XM, Wu SJ, Guan HL, Shang CJ. Stress-strain behavior of multi-phase high performance structural steel. Sci. China Technol. Sci, 2012, 55, 1791.

[25]	Shi J, Sun XJ, Wang MQ, Hui WJ, Dong H, Cao WQ. Enhanced work-hardening behavior and mechanical properties in ultrafine-grained steels with large-fractioned metastable austenite. Scripta Mater, 2010, 63, 815.

[26]	Xie ZJ, Shang CJ, Zhou WH, Wu BB. Effect of retained austenite on ductility and toughness of a low alloyed multi-phase steel. Acta Metall. Sin., 2016, 52, 224.

[27]	Kim KJ, Schwartz LH. On the effects of intercritical tempering on the impact energy of Fe-9Ni-0.1C. Mater. Sci. Eng., 1978, 33, 5.

[28]	Pampillo CA, Paxton HW. The effect of reverted austenite on the mechanical properties and toughness of 12 Ni and 18 Ni (200) maraging steels. Metall. Mater. Trans. B, 1972, 3, 2895.

[29]	Antolovich SD, Singh B. On the toughness increment associated with the austenite to martensite phase transformation in TRIP steels. Metall. Mater. Trans. B, 1971, 2, 2135.

[30]	Zhou WH, Xie ZJ, Guo H, Shang CJ. Regulation of multi-phase microstructure and mechanical properties in a 700 MPa grade low carbon lowalloy steel with good ductility. Acta Metall. Sin., 2015, 51, 407.

[31]	Mukherjee M, Tiwari S, Bhattacharya B. Evaluation of factors affecting the edge formability of two hot rolled multiphase steels. Int. J. Miner. Metall. Mater, 2018, 25, 199.

[32]	Kuang CF, Zheng ZW, Wang ML, Xu Q, Zhan SG. Effect of hot-dip galvanizing processes on the micro-structure and mechanical properties of 600-MPa hot-dip galvanized dual-phase steel. Int. J. Miner. Metall. Mater, 2017, 24, 1379.

[33]	Xie ZJ, Fang YP, Han G, Guo H, Misra RDK, Shang CJ. Structure-property relationship in a 960 MPa grade ultrahigh strength low carbon niobium-vanadium mi-croalloyed steel: The significance of high frequency induction tempering. Mater. Sci. Eng. A, 2014, 618, 112.

[34]	Van Der Zwaag S, Zhao L, Kruijver SO, Sietsma J. Thermal and mechanical stability of retained austenite in aluminum-containing multiphase TRIP steels. ISIJ Int., 2002, 42, 1565.

[35]	Edmonds DV, He K, Rizzo FC, De Cooman BC, Matlock DK, Speer JG. Quenching and partitioning martensite—A novel steel heat treatment. Mater. Sci. Eng. A, 2006, 438-440, 25.

[36]	Syn CK, Fultz B, Morris JW. Mechanical stability of retained austenite in tempered 9Ni steel. Metall. Trans. A, 1978, 9, 1635.

[37]	Fultz B, Kim JI, Kim YH, Morris JW. The chemical composition of precipitated austenite in 9Ni steel. Metall. Trans. A, 1986, 17, 967.

[38]	Fultz B, Kim JI, Kim YH, Kim HJ, Fior GO, Morris JW. The stability of precipitated austenite and the toughness of 9Ni steel. Metall. Trans. A, 1985, 16, 2237.

[39]	Yang YH, Cai QW, Tang D, Wu HB. Precipitation and stability of reversed austenite in 9Ni steel. Int. J. Miner. Metall. Mater, 2010, 17, 587.

[40]	Xu HF, Zhao J, Cao WQ, Shi J, Wang CY, Wang C, Li J, Dong H. Heat treatment effects on the micro-structure and mechanical properties of a medium manganese steel (0.2C-5Mn). Mater. Sci. Eng. A, 2012, 532, 435.

[41]	Lee YK, Han J. Current opinion in medium manganese steel. Mater. Sci. Technol, 2015, 31, 843.

[42]	Hu J, Du LX, Xu W, Zhai JH, Dong Y, Liu YJ, Msra RDK. Ensuring combination of strength, ductility and toughness in medium-manganese steel through optimization of nano-scale metastable austenite. Mater. Charact, 2018, 136, 20.

[43]	Xie ZJ, Shang CJ, Subramanian SV, Ma XP, Misra RDK. Atom probe tomography and numerical study of austenite stabilization in a low carbon low alloy steel processed by two-step intercritical heat treatment. Scripta Mater, 2017, 137, 36.

[44]	Takaki S, Fukunaga K, Syarif J, Tsuchiyama T. Effect of grain refinement on thermal stability of metastable austenitic steel. Mater. Trans., 2004, 45, 2245.

[45]	Jiang BH, Sun LM, Li RC, Hsu TY. Influence of austenite grain size on γ-ε martensitic transformation temperature in Fe-Mn-Si alloys. Scripta Metall. Mater, 1995, 33, 63.

[46]	Yang HS, Bhadeshia HKDH. Austenite grain size and the martensite-start temperature. Scripta Mater, 2009, 60, 493.

[47]	Jimenez-Melero E, Van Dijk NH, Zhao L, Sietsma J, Offerman SE, Wright JP, van der Zwaag S. Martensitic transformation of individual grains in low-alloyed TRIP steels. Scripta Mater, 2007, 56, 421.

[48]	Hashimoto S, Ikeda S, Sugimoto KI, Myake S. Effects of Nb and Mo addition to 0.2%C-1.5%Si-1.5%Mn steel on mechanical properties of hot rolled TRIP-aided steel sheets. ISIJ Int., 2004, 44, 1590.

[49]	Heslop J, Petch NJ. The ductile-brittle transition in the fracture of α-iron: II. Philos. Mag, 1958, 3, 1128.

[50]	Petch NJ. The ductile-brittle transition in the fracture of α-iron: I. Philos. Mag., 1958, 3, 1089.

[51]	Antolovich SD, Saxena A, Chanani GR. Increased fracture toughness in a 300 grade maraging steel as a result of thermal cycling. Metall. Trans., 1974, 5, 623.

[52]	Gui XL, Wang KK, Gao GH, Msra RDK, Tan ZL, Bai BZ. Rolling contact fatigue of bainitic rail steels: The significance of microstructure. Mater. Sci. Eng. A, 2016, 657, 82.

[53]	Gao GH, Zhang BX, Cheng C, Zhao P, Zhang H, Bai BZ. Very high cycle fatigue behaviors of bainite/martensite multiphase steel treated by quenching-partitioning-tempering process. Int. J. Fatigue, 2016, 92, 203.

[54]	Wang XL, Nan YR, Xie ZJ, Tsai YT, Yang JR, Shang CJ. Influence of welding pass on microstructure and toughness in the reheated zone of multi-pass weld metal of 550 MPa offshore engineering steel. Mater. Sci. Eng. A, 2017, 702, 196.

[55]	Wang XL, Dong LM, Yang WW, Zhang Y, Wang XM, Shang CJ. Effect of Mn. Ni, Moproportion on microstructure and mechanical properties of weld metal of K65 pipeline steel. Acta Metall. Sin, 2016, 52, 649.

[56]	Wang XL, Tsai YT, Yang JR, Wang ZQ, Li XC, Shang CJ, Misra RDK. Effect of interpass temperature on the microstructure and mechanical properties of multipass weld metal in a 550-MPa-grade offshore engineering steel. Weld. World, 2017, 61, 1155.

[57]	Wang XL, Shang CJ, Wang XM. Characterization of the multi-pass weld metal and the effect of post-weld heat treatment on its microstructure and toughness, [in]. HSLA Steels 2015, Microalloying 2015 & Offshore Engineering Steels 2015, 2015 481.

[58]	Wang XL, Wang XM, Shang CJ, Msra RDK. Characterization of the multi-pass weld metal and the impact of retained austenite obtained through intercritical heat treatment on low temperature toughness. Mater. Sci. Eng. A, 2016, 649, 282.

[59]	Dong LM, Yang L, Dai J, Zhang Y, Wang XL, Shang CJ. Effect of Mn, Ni, Mo contents on microstructure transition and low temperature toughness of weld metal for K65 hot bending pipe. Acta. Metall. Sin., 2017, 53, 657.