Abstract
In this paper, we present the simulation of the eutectic phase transitions in the Pt–C system, in terms of both freezing and melting, using the multi-phase-field model. The experimentally obtained heat-extraction and -injection rates associated with the induction of freezing and melting are converted into the corresponding rates for microstructure-scale simulations. In spite of the extreme differences in the volume fractions of the FCC–Pt-rich phase on the one hand and graphite (C) on the other, satisfactory results for the kinetics of solidification and melting have been obtained, involving reasonable offsets in temperature, inducing freezing and melting, with respect to the equilibrium eutectic temperature. For freezing in the simulations, the needle/rod-like morphology, as experimentally observed, was reproduced for different heat extraction rates. The seemingly anomalous peak characterizing the simulated freezing curves is ascribed to the speed up of the solidification process due to the curvature effect. Similarly, a peak is observed in the experimental freezing curves, also showing up more clearly with increasing freezing rates. Melting was simulated starting from a frozen structure produced by a freezing simulation. The simulations reproduce the experimental melting curves and, together with the simulated freezing curves, help to understand the phase transition of the Pt–C eutectic. Finally, the effect of metallic impurities was studied. As shown for Au, impurities affect the morphology of the eutectic structure, their impact increasing with the impurity content, i.e., they can act as modifiers of the structure, as earlier reported for irregular eutectics.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
H. Preston-Thomas, Metrologia 27, 3 (1990)
E.R. Woolliams, G. Machin, D.H. Lowe, R. Winkler, Metrologia 43, 11 (2006)
Y. Yamada, J. Mater. Soc. India 20, 183 (2005)
M. Ode, N. Sasajima, Y. Yamada, P. Bloembergen, H. Onodera, Int. J. Thermophys. 32, 2610 (2011)
K.A. Jackson, J.D. Hunt, Trans. Met. Soc. AIME 236, 1129 (1966)
N. Sasajima, Y. Yamada, Y. Wang, P. Bloembergen, T. Wang, J. Le Coze, J. Alloys Compd. 452, 61 (2008)
P. Magnin, W. Kurz, Acta Metall. 35, 1119–1128 (1987)
I. Steinbach, F. Pezzolla, B. Nestler, M. Seeßelberg, R. Prieler, G.J. Schmitz, J.L.L. Rezende, Physica D 94, 135–147 (1996)
W. Guo, I. Steinbach, Int. J. Mater. Res. 101, 480 (2010)
http://www.openphase.de/. Accessed 26 Oct 2015
P. Bloembergen, Y. Yamada, N. Sasajima, Y. Wang, T. Wang, Metrologia 44, 279 (2007)
P. Bloembergen, Y. Yamada, N. Yamamoto, J. Hartmann, Temp. Meas. Control Sci. Ind. 7, 291–296 (2003)
M. Sadli, Y. Yamada, T. Wang, H. Yoon, P. Bloembergen, G. Machin et al., Acta Metrol. Sin. 29, 59–64 (2008)
W. Dong, P. Bloembergen, T. Wang, Y.Y. Duan, Int. J. Thermophys. 32, 2680–2695 (2011)
B. Huang, C.G. Li, L.K. Shi, G.Zh. Qiu, T. Y. Zuo, Handbook of Non-ferrous Metals (2009), pp. 376–379 [in Chinese]
http://www.calphad.com/. Accessed 26 Oct 2015
http://www.thermocalc.com/. Accessed 26 Oct 2015
Thermocalc SSOL4—SGTE Solution Database, Version 4, Aug 22th (2012)
J.W. Arblaster, Platin. Met. Rev. 49(3), 141–149 (2005)
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Monas, A., Bloembergen, P., Dong, W. et al. Simulations of the Eutectic Transformations in the Platinum–Carbon System. Int J Thermophys 36, 3366–3383 (2015). https://doi.org/10.1007/s10765-015-1999-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10765-015-1999-8