Thermo-Kinetic Understanding of the Correlation Between Austenite Reverse Transformation and Mechanical Properties for Medium Manganese Steel

doi:10.1007/s40195-025-01849-7

Abstract

Abstract:

How to describe the austenite reverse transformation (ART) has always been considered as a key problem of controlling microstructures and mechanical properties in high-strength steels. So far, numerous studies have been conducted, unfortunately, without fully considering diffusion of elements, interface migration, and interaction between trans-interface diffusion and interface migration, as well as synergy of thermodynamic and kinetic for interfacial migration. A more flexible modeling for the ART is herein developed using thermodynamic extremal principle, where the concept of trans-interface diffusion in two steps, i.e., from the parent phase to the interface and from the interface to the product phase, as well as the Gibbs energy balance approach, was introduced to predict the behavior of interface migration and element trans-interface diffusion within the migrating interface. Subsequently, the thermodynamic driving force ΔG and the effective kinetic energy barrier Q_eff for the ART were also analytically performed, as well as a unified expression for so-called generalized stability (GS). It is demonstrated that the higher driving force in the ART generally results in the increased yield strength, while the larger GS tends to yield improved uniform elongation, thus forming a correspondence between the thermo-kinetics trade-off and the strength-ductility trade-off. Applying a proposed criterion of high ΔG-high GS, the present model can be adopted to design the ART, which will produce the austenite microstructure with high strength and high plasticity, as evidenced by the current experiments.

Key words: Austenite reverse transformation, Thermodynamic extremal principle, Thermo-kinetic correlation, Generalized stability, Material property

Yong Hou, Haiyu Liu, Yao Wang, Yu Zhang, Yayun Zhang, Feng Liu. Thermo-Kinetic Understanding of the Correlation Between Austenite Reverse Transformation and Mechanical Properties for Medium Manganese Steel[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(7): 1195-1206.

Figures/Tables 10

Fig. 1 Schematic diagram for the planar interface ($\text{I}$) upon austenite reverse transformation, which separates the austenite ($\gamma$) and the ferrite ($\alpha$) and moves toward the ferrite with the velocity $v$ along the direction normal to the γ/α interface. Note that a single closed system is considered because there is no solute fluxed at the interface of the austenite ($\text{L}$) and the ferrite ($\text{R}$), which is different from the inner interface ($\text{I}$), the austenite ($\gamma$) and the ferrite ($\alpha$) with concentration ($u_{\alpha }^{i},u_{\gamma }^{i},u_{\alpha }^{{i*}},u_{\gamma }^{{i*}}$), solute fluxes ($J_{\alpha }^{i}$, $J_{\gamma }^{i},J_{\alpha }^{{i*}},J_{\gamma }^{{i*}}$), and chemical potential ($\mu _{\alpha }^{i},\mu _{\gamma }^{i},\mu _{\alpha }^{{i*}},\mu _{\gamma }^{{i*}}$). The lengths of $\text{LI}$ and $\text{LR}$ are $l$ and $S$, respectively

Fig. 2 Concentration profiles of a carbon and b manganese are plotted at different time: the initial time t = 0, an intermediate time t, and the infinite time t=$\infty$ when the austenite-ferrite equilibrium is reached

Fig. 3 Microstructure of the specimen before the ART. a An EBSD map filled with lath martensite before the heat treatment, in Fe-0.92C-8.06Mn (in at.%) alloy. b Counts of different lath widths in a, where the mean width is 1.01 μm

Fig. 4 Evolution of the calculated phase transformation dynamics. a Dilatation of the sample as a function of temperature. b Variation of austenite fraction with transformed time at 620, 640, 660 ℃ calculated by the current model and the Kuang’s model. c, d C and Mn diffusion profiles at various time at 660 ℃, respectively. Note that the $\gamma$ phase grows from the left to the right in the cell of the $\alpha$ phase

Table 1 Thermodynamic and kinetic factors governing the phase transformation at the three considered temperatures

	620 ℃	640 ℃	660 ℃
${\chi }_{\text{C}}$ (J mol⁻¹ at.%⁻¹)	290.1	266.7	244.0
${\chi }_{\text{Mn}}$ (J mol⁻¹ at.%⁻¹)	− 233.4	− 208.9	− 233.3
${f}_{\gamma }^{\text{eq}}$	0.27	0.52	0.78

Fig. 5 Evolution of experimental phase transformation dynamics. a Dilatation of the samples as a function of time at 620, 640, 660 ℃, respectively. b XRD patterns of the samples treated for 30 min at different temperatures. c Volume fraction of austenite treated at different temperatures for 30 min. d Calculated evolution and experimental evolution of γ fraction as functions of time

Fig. 6 Changes in Gibbs free energy of phases. a Gibbs free energy of the austenite phase as a function of temperature and carbon content. b Gibbs free energy of the ferrite phase as a function of temperature and manganese content (Thermo-Calc)

Fig. 7 Evolution of the thermodynamic driving force, the kinetic energy barrier, and generalized stability. a Evolution of thermodynamic driving force and the kinetic energy barrier as a function of the isothermal temperature. b Variation of the driving force and generalized stability with isothermal temperature and transition fraction

Fig. 8 Mechanical properties: a engineering stress-strain curves of the ART620-180, ART620-600, ART620-1200, and ART620-1800 samples, b summary of yield strength and uniform elongation

Table 2 Transition fractions at different temperature and holding time (come from Fig. 5(d)) and the corresponding symbols (shown in Fig. 8(b))

	180 s	600 s	1200 s	1800 s
620 ℃	0.101 (A1)	0.120 (A2)	0.143 (A3)	0.161 (A4)
640 ℃	0.190 (B1)	0.217 (B2)	0.246 (B3)	0.274 (B4)
660 ℃	0.240 (C1)	0.279 (C2)	0.341 (C3)	0.395 (C4)

References 36

[1]	D.W. Suh, S.J. Kim, Scr. Mater. 126, 63 (2017)
[2]	Y. Ma, Mater. Sci. Technol. 33, 1713 (2017)
[3]	J. Shi, H.F. Xu, J. Zhao, W.Q. Cao, C. Wang, C.Y. Wang, J. Li, H. Dong, Acta Metall. Sin.-Engl. Lett. 25, 111 (2012)
[4]	S. Ahmad, L.F. Lv, L.M. Fu, H.R. Wang, W. Wang, A.D. Shan, Acta Metall. Sin.-Engl. Lett. 32, 361 (2019)
[5]	B.J. Hu, Q.Y. Zheng, C.N. Jia, P. Liu, Y.K. Luan, C.W. Zheng, D.Z. Li, Acta Metall. Sin.-Engl. Lett. 35, 1068 (2022)
[6]	T. Akbay, R.C. Reed, C. Atkinson, Acta Mater. 42, 1469 (1994)
[7]	C. Atkinson, T. Akbay, R.C. Reed, Acta Mater. 43, 2013 (1995)
[8]	J.W. Christian, Equilibrium and general kinetic theory(Pergamon Press, Oxford, 1975), p. 19
[9]	G.P. Krielaart, J. Sietsma, S. Van Der Zwaag, Mater. Sci. Eng. A 237, 216 (1997)
[10]	M.G. Mecozzi, C. Bos, J. Sietsma, Acta Mater. 88, 302 (2015)
[11]	D. An, S. Pan, Q. Ren, Q. Li, B.W. Krakauer, M. Zhu, Scr. Mater. 178, 207 (2020)
[12]	W.W. Kuang, H.F. Wang, X. Li, J.B. Zhang, Q. Zhou, Y.H. Zhao, Acta Mater. 159, 16 (2018)
[13]	J. Odqvist, M. Hillert, J. Ågren, Acta Mater. 50, 3213 (2002)
[14]	J. Svoboda, F.D. Fischer, P.H. Mayrhofer, Acta Mater. 56, 4896 (2008)
[15]	F.D. Fischer, J. Svoboda, H. Petryk, Acta Mater. 67, 1 (2014)
[16]	F.D. Fischer, K. Hackl, J. Svoboda, Acta Mater. 108, 347 (2016)
[17]	W.W. Kuang, H.F. Wang, J.B. Zhang, F. Liu, Acta Mater. 120, 415 (2016)
[18]	F. Liu, T.L. Wang, Acta Metall. Sin. 57, 55 (2020)
[19]	J. Sietsma, S. van der Zwaag, Acta Mater. 52, 4143 (2004)
[20]	C. Bos, J. Sietsma, Scr. Mater. 57, 1085 (2007)
[21]	M. Gouné, F. Danoix, J. Ågren, Y. Bréchet, C.R. Hutchinson, M. Militzer, G. Purdy, S. van der Zwaag, H. Zurob, Mater. Sci. Eng. R 92, 1 (2015)
[22]	O. Dmitrieva, D. Ponge, G. Inden, J. Millán, P. Choi, J. Sietsma, D. Raabe, Acta Mater. 59, 364 (2011)
[23]	M. Ollat, M. Militzer, V. Massardier, D. Fabregue, E. Buscarlet, F. Keovilay, M. Perez, Comp. Mater. Sci. 149, 282 (2018)
[24]	D.M. Herlach, Adv. Space Res. 11, 255 (1991)
[25]	L.K. Huang, W.T. Lin, Y.B. Zhang, D. Feng, Y.J. Li, X. Chen, K. Niu, F. Liu, Acta Mater. 201, 167 (2020)
[26]	W.D. Murray, F. Landis, J. Heat Transf.-Trans. ASME 81, 106 (1959). https://doi.org/10.1115/1.4008149
[27]	J.T. Benzing, A. Kwiatkowski da Silva, L. Morsdorf, J. Bentley, D. Ponge, A. Dutta, J. Han, J.R. McBride, B. Van Leer, B. Gault, D. Raabe, J.E. Wittig, Acta Mater. 166, 512 (2019) DOI
[28]	D. An, S.L. Chen, D.K. Sun, S.Y. Pan, B.W. Krakauer, M.F. Zhu, Comp. Mater. Sci. 166, 210 (2019)
[29]	L. Chen, X.R. Zhang, B.L. Deng, Heat Transfer. Eng. 37, 302 (2016)
[30]	Y. Zhang, Y.Q. He, Y.Y. Zhang, S.J. Song, F. Liu, Scr. Mater. 227, 115311 (2023)
[31]	Y.Q. He, S.J. Song, J.L. Du, H.R. Peng, Z.G. Ding, H.Y. Hou, L.K. Huang, Y.C. Liu, F. Liu, J. Mater. Sci. Technol. 127, 225 (2022)
[32]	Y.Y. Zhang, L.K. Huang, K.X. Song, F. Liu, J. Mater. Res. Technol. 30, 5145 (2024)
[33]	P. Wu, Y.B. Zhang, J.Q. Hu, S.J. Song, Y. Li, H.Y. Wang, G. Yuan, Z.D. Wang, S.Z. Wei, F. Liu, J. Mater. Sci. Technol. 134, 163 (2023)
[34]	T.P. Zhou, C.Y. Wang, C. Wang, W.Q. Cao, Z.J. Chen, Mater. Sci. Eng. A 798, 140147 (2020)
[35]	F. Liu, J. Mater. Sci. Technol. 155, 72 (2023)
[36]	H.Y. Liu, P. Wu, K.X. Song, Y.X. Zhang, G. Yuan, F. Liu, J. Mater. Res. Technol. 32, 2651 (2024)