Monte Carlo study on abnormal growth of Goss grains in Fe-3%Si steel induced by second-phase particles

Dong-qun Xin; Cheng-xu He; Xue-hai Gong; Hao Wang; Li Meng; Guang Ma; Peng-fei Hou; Wen-kang Zhang

doi:10.1007/s12613-016-1363-4

International Journal of Minerals, Metallurgy, and Materials ›› 2016, Vol. 23 ›› Issue (12) : 1397 -1403. DOI: 10.1007/s12613-016-1363-4

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Monte Carlo study on abnormal growth of Goss grains in Fe-3%Si steel induced by second-phase particles

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Abstract

The selective abnormal growth of Goss grains in magnetic sheets of Fe-3%Si (grade Hi-B) induced by second-phase particles (AlN and MnS) was studied using a modified Monte Carlo Potts model. The starting microstructures for the simulations were generated from electron backscatter diffraction (EBSD) orientation imaging maps of recrystallized samples. In the simulation, second-phase particles were assumed to be randomly distributed in the initial microstructures and the Zener drag effect of particles on Goss grain boundaries was assumed to be selectively invalid because of the unique properties of Goss grain boundaries. The simulation results suggest that normal growth of the matrix grains stagnates because of the pinning effect of particles on their boundaries. During the onset of abnormal grain growth, some Goss grains with concave boundaries in the initial microstructure grow fast abnormally and other Goss grains with convex boundaries shrink and eventually disappear.

Keywords

silicon steel / grain growth / second phase particles / Monte Carlo simulation

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Dong-qun Xin, Cheng-xu He, Xue-hai Gong, Hao Wang, Li Meng, Guang Ma, Peng-fei Hou, Wen-kang Zhang. Monte Carlo study on abnormal growth of Goss grains in Fe-3%Si steel induced by second-phase particles. International Journal of Minerals, Metallurgy, and Materials, 2016, 23(12): 1397-1403 DOI:10.1007/s12613-016-1363-4

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References

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[1]	Mishra S., Därmann C., Lücke K. On the development of the Goss texture in iron-3% silicon. Acta Metall., 1984, 32(12): 2185.

[2]	Goss N. New development in electrical strip steels characterized by fine grain structure approaching the properties of a single crystal. Trans. Am. Soc. Met., 1935, 23, 511.

[3]	Harase J., Shimizu R., Dingley D.J. Texture evolution in the presence of precipitates in Fe-3% Si alloy. Acta Metall. Mater., 1991, 39, 763.

[4]	Lin P., Palumbo G., Harase J., Aust K.T. Coincidence site lattice (CSL) grain boundaries and Goss texture development in Fe-3% Si alloy. Acta Metall., 1996, 44(12): 4677.

[5]	Harase J., Shimizu R., Kim J.K., SooWoo J. The role of high energy boundaries and coincidence boundaries in the secondary recrystallization of grain-oriented silicon steel. Met. Mater., 1999, 5(5): 429.

[6]	Hayakawa Y., Szpunar J.A., Palumbo G., Lin P. The role of grain boundary character distribution in Goss texture development in electrical steels. J. Magn. Magn. Mater., 1996, 160, 143.

[7]	Hayakawa Y., Szpunar J.A. The role of grain boundary character distribution in secondary recrystallization of electrical steels. Acta Mater., 1997, 45(3): 1285.

[8]	Hayakawa Y., Szpunar J.A. A new model of Goss texture development during secondary recrystallization of electrical steel. Acta Mater., 1997, 45(11): 4713.

[9]	Hwang N.M., Lee S.B., Kim D.Y. Abnormal grain growth by solid-state wetting along grain boundary or triple junction. Scripta Mater., 2001, 44(7): 1153.

[10]	Lee D.K., Ko K.J., Lee B.J., Hwang N.M. Monte Carlo simulations of abnormal grain growth by sub-boundary-enhanced solid-state wetting. Scripta Mater., 2008, 58(8): 683.

[11]	Ko K.J., Rollett A.D., Hwang N.M. Abnormal grain growth of Goss grains in Fe-3% Si steel driven by sub-boundary-enhanced solid-state wetting: analysis by Monte Carlo simulation. Acta Mater., 2010, 58(13): 4414.

[12]	Zener C. Private communication to CS Smith, Grains, phases and interfaces: an interpretation of microstructure. Trans. AIME, 1949, 175, 15.

[13]	Humphreys F.J., Hatherly M. Recrystallization and Related Annealing Phenomena, 1995, Oxford, Pergamon Press

[14]	Ramírez-López A., Soto-Cortés G., González-Trejo J., Muñoz-Negrón D. Computational algorithms for simulating the grain structure formed on steel billets using cellular automaton and chaos theories. Int. J. Miner., Metall. Mater., 2011, 18(1): 24.

[15]	Ramírez-López A., Palomar-Pardavé M., Muñoz-Negrón D., Duran-Valencia C., López-Ramirez S., Soto-Cortés G. A cellular automata model for simulating grain structures with straight and hyperbolic interfaces. Int. J. Miner., Metall. Mater., 2012, 19(8): 699.

[16]	Anderson M.P., Srolovitz D.J., Grest G.S., Sahni P.S. Computer simulation of grain growth: I. Kinetics. Acta Metall., 1984, 32(5): 783.

[17]	Srolovitz D.J., Anderson M.P., Sahni P.S., Grest G.S. Computer simulation of grain growth: II. Grain size distribution, topology, and local dynamics. Acta Metall., 1984, 32(5): 793.

[18]	Wolf D. A read-shockley model for high-angle grain boundaries. Scripta Metall., 1989, 23(10): 1713.

[19]	Feltham P. Grain growth in metals. Acta Metall., 1957, 5(2): 97.

[20]	Chen N., Zaefferer S., Lahn L., Günther K., Raabe D. Effects of topology on abnormal grain growth in silicon steel. Acta Mater., 2003, 51(6): 1755.

[21]	Mullins W.W. Two-dimensional motion of idealized grain boundaries. J. Appl. Phys., 1956, 27(8): 900.

[22]	von Neumann J. Herring C. Written discussion of grain shapes and other metallurgical applications of topology. Metal Interfaces, 1952, Cleveland, American Society for Metals, 108.