Micro-scale Cellular Automaton Modeling of Interface Evolution During Reaustenitization from Pearlite Structure in Steels

doi:10.1007/s40195-018-0706-8

Abstract

Abstract:

A modified cellular automaton model is developed to depict the interface evolution inside the cementite plus ferrite lamellar microstructures during the reaustenitization of a pearlite steel. In this model, migrations of both the austenite-ferrite and austenite-cementite interfaces coupled with the carbon diffusion and redistribution are integrated. The capillarity effect derived from local interface curvatures is also carefully considered by involving the concentration given by the phase diagram modified by the Gibbs-Thomson effect. This allows the interface evolution from a transient state to a steady state under different annealing conditions and various interlamellar spacings to be simulated. The proposed cellular automaton approach could be readily used to describe the kinetics of austenite formation from the lamellar pearlites and virtually reveal the kinematics of the moving interfaces from the microstructural aspect.

Key words: Austenite formation, Lamellar pearlite, Interface evolution, Cellular automaton, Microstructural modeling

Gang Shen, Cheng-Wu Zheng, Jian-Feng Gu, Dian-Zhong Li. Micro-scale Cellular Automaton Modeling of Interface Evolution During Reaustenitization from Pearlite Structure in Steels[J]. Acta Metallurgica Sinica (English Letters), 2018, 31(7): 713-722.

Figures/Tables 14

Fig. 1 Schematic representation of microstructure during dissolution of pearlite into austenite a and variation of carbon content along the dashed line A-A′ b

Fig. 2 Schematic representation of linearized Fe-C phase diagram with Gibbs-Thomson effect and definition of concentrations imposed at interface for CA calculation

Table 1 Key parameters used in simulations

Symbol	Definition and unit	Value	Refs.
\({\text{A}}_{{{\text{c}}1}}\)	Austenite formation start temperature (K)	996.0	[31]
\({\text{A}}_{{{\text{c}}3}}\)	Ferrite dissolution finish temperature (K)	\(- \,0.004021 \cdot T + 4.7651\)	[31]
\(A_{\text{ccm}}\)	Cementite dissolution finish temperature (K)	\(0.003255 \cdot T - 2.4817\)	[31]
\(M^{\alpha \gamma }\)	Mobility of \(\alpha /\gamma\) interface (mol m J^-1 s^-1)	\(0.5 \cdot { \exp }\left( { - \,140000/\left( {RT} \right)} \right)\)	[20]
\(M^{\gamma \theta }\)	Mobility of \({\gamma \mathord{\left/ {\vphantom {\gamma \theta }} \right. \kern-0pt} \theta }\) interface (mol m J^-1 s^-1)	\(0.05 \cdot { \exp }\left( { - \,140000/\left( {RT} \right)} \right)\)	-
\(D_{\text{c}}^{\gamma }\)	Carbon diffusion coefficient in austenite (m² s^-1)	\(1.5 \times 10^{ - 5} { \exp }\left( { - \,142000/\left( {RT} \right)} \right)\).	[20]
\(\varGamma_{\gamma /\alpha }\)	Gibbs-Thomson coefficient of \({\alpha \mathord{\left/ {\vphantom {\alpha \gamma }} \right. \kern-0pt} \gamma }\) interface (K m)	\(2 \times 10^{ - 7}\)	[25]
\(\varGamma_{\gamma /\theta }\)	Gibbs-Thomson coefficient of \({\gamma \mathord{\left/ {\vphantom {\gamma \theta }} \right. \kern-0pt} \theta }\) interface (K m)	\(2 \times 10^{ - 7}\)	[25]

Fig. 3 Schematic representation of sidewise planar growth of austenite into ferrite and cementite (rγ/α and rγ/θ are positions of the moving austenite fronts into ferrite and cementite, respectively)

Fig. 4 Variation of carbon concentration along dotted line indicated in Fig. 3 at different time

Fig. 5 Change in austenite interface positions predicted by CA and DICTRA

Fig. 6 Schematic representation of initial structure for austenite growing within pearlite lamella

Fig. 7 Austenite growing inside pearlite lamella with interlamellar spacing of 0.5 μm at 1073 K: a evolution of phase interface; b carbon concentration field at steady-state stage

Fig. 8 Change in local carbon concentration profile along moving interface of OD as shown in Fig. 7

Fig. 9 Change in local velocities of the \({\gamma \mathord{\left/ {\vphantom {\gamma \alpha }} \right. \kern-0pt} \alpha }\) interface (\(v_{y}^{\gamma /\alpha }\)) at different positions of B, C and D (as shown in Fig. 7) of moving austenite interface

Fig. 10 Interface shapes of growing austenite and carbon concentration profiles at steady state with varied carbon diffusion coefficient: a 2.0 \(D_{\text{C}}^{\gamma }\); b \(D_{\text{C}}^{\gamma }\); c 0.5 \(D_{\text{C}}^{\gamma }\)

Fig. 11 Evolution of velocity at position D of moving interface (\(v_{y}\)) with varying carbon diffusivity in austenite

Fig. 12 Interface shapes and carbon concentration profile of growing austenite at steady state with varied interlamellar spacings of 0.2 μm a, 0.4 μm b and 0.8 μm c

Fig. 13 Growth rate (\(v\)) and parabolic coefficient of interface shapes at steady state during austenite formation from pearlite with various interlamellar spacings

References

[1]	D.A. Porter, K.E. Easterling, London, 1992)
[2]	S. Offerman, N. Van Dijk, J. Sietsma, S. Grigull, E. Lauridsen,L. Margulies, H. Poulsen, M.T. Rekveldt,Science 298, 1003 (2002)
[3]	V. Savran, S. Offerman, J. Sietsma, Metall. Mater. Trans. A 41,583 (2010)
[4]	C.C. Tasan, M. Diehl, D. Yan, M. Bechtold, F. Roters, L.Schemmann, C. Zheng, N. Peranio, D. Ponge, M. Koyama, K.Tsuzaki, D. Raabe, Annu. Rev. Mater. Res. 45, 391(2015)
[5]	A. Ramazani, S. Bruehl, T. Gerber, W. Bleck, U. Prahl, Mater.Des. 57, 479(2014)
[6]	Q. Lai, M. Goune′, A. Perlade, T. Pardoen, P. Jacques, O.Bouaziz, Y. Bre′chet, Metall. Mater. Trans. A 47, 3375 (2016)
[7]	H. Azizi-Alizamini, M. Militzer, W.J. Poole, Metall. Mater.Trans. A 42, 1544 (2011)
[8]	V. Savran, Y. Van Leeuwen, D. Hanlon, C. Kwakernaak, W.Sloof, J. Sietsma, Metall. Mater. Trans. A 38, 946 (2007)
[9]	D. Shtansky, K. Nakai, Y. Ohmori, Acta Mater. 47, 2619(1999)
[10]	Y. Li, P. Choi, S. Goto, C. Borchers, D. Raabe, R. Kirchheim,Acta Mater. 60, 4005(2012)
[11]	M. De Graef, M. Kral, M. Hillert, JOM 58, 25 (2006)
[12]	F.C. Cerda, I. Sabirov, C. Goulas, J. Sietsma, A. Monsalve, R.Petrov, Mater. Des. 116, 448(2017)
[13]	D. Gaude-Fugarolas, H. Bhadeshia, J. Mater. Sci. 38, 1195(2003)
[14]	Z. Yang, Z. Yang, Y. Xia, C. Zhang, Acta Metall. Sin. 49, 890(2013). (in Chinese)
[15]	Z. Li, Z. Wen, F. Su, R. Zhang, Z. Zhou, J. Alloys Compd. 727,1050(2017)
[16]	F. Caballero, C. Capdevila, Mater. Sci.Technol. 17, 686(2001)
[17]	K.G.F. Janssens,Computational Materials Engineering an Introduction to Microstructure Evolution (Academic Press,Amsterdam Boston, 2007)
[18]	D. Raabe, Annu. Rev. Mater. Res. 32, 53(2002)
[19]	B. Yang, L. Chuzhoy, M. Johnson, Comput. Mater. Sci. 41, 186(2007)
[20]	C. Zheng, D. Raabe, Acta Mater. 61, 5504(2013)
[21]	B. Zhu, Y. Zhang, C. Wang, P.X. Liu, W.K. Liang, J. Li, Metall.Mater. Trans. A 45, 3161 (2014)
[22]	C. Halder, L. Madej, M. Pietrzyk, Arch. Civ. Mech. Eng. 14, 96(2014)
[23]	B. Zhu, M. Militzer, Metall. Mater. Trans. A 46, 1073 (2015)
[24]	M. Perez, Scr. Mater. 52, 709(2005)
[25]	A. Jacot, M. Rappaz, R. Reed, Acta Mater. 46, 3949(1998)
[26]	B. Su, Z. Han, B. Liu, ISIJ Int. 53, 527(2013)
[27]	K. Kremeyer, J. Comput. Phys. 142, 243(1998)
[28]	M. Enomoto, K. Hayashi, J. Mater. Sci. 50, 6786(2015)
[29]	Y.J. Lan, D.Z. Li, Y.Y. Li, Acta Mater. 52, 1721(2004)
[30]	J.E. Guyer, D. Wheeler, J.A. Warren, Comput. Sci. Eng. 11, 6(2009)
[31]	M. Militzer, H. Azizi-Alizamini, Solid State Phenom. 172, 1050(2011)
[32]	J.O. Andersson, T. Helander, L. Ho¨glund, P. Shi, B. Sundman,Calphad 26, 273 (2002)
[33]	G. Roberts, R. Mehl, Trans. Am. Soc. Met. 31, 613(1943)
[34]	F. Caballero, C. Capdevila, C.G. Metall. Mater.Trans. A 32, 1283 (2001)
[35]	L. Schemmann, S. Zaefferer, D. Raabe, F. Friedel, D. Mattissen,Acta Mater. 95, 386(2015)
[36]	Y. Xia, M. Enomoto, Z. Yang, Z. Li, C. Zhang, Philos. Mag. 93,1095(2013)