Abstract
We describe two new methods for locating the dew/bubble curves of fluids. One is a numerical method and the other an analytical method based on the use of series expansions. The utility of these two methods is illustrated by application to a simple one-component fluid model and to several model polydisperse fluids. The numerical method is based on a new geometric representation of the equilibrium conditions-similar in spirit to the geometric representations often used for solving the equilibrium conditions of pure fluids. Our calculations show that the series-expansion technique can be quite effective at producing accurate representations of the phase boundaries.
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Kincaid, J.M., Shon, K.B. & Fescos, G. New methods for calculating the dew/bubble curves of classical model fluids. J Stat Phys 57, 937–963 (1989). https://doi.org/10.1007/BF01022842
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DOI: https://doi.org/10.1007/BF01022842