Entropy Scaling for Diffusion Coefficients in Fluid Mixtures
Abstract
Entropy scaling is a powerful technique that has been used for predicting transport properties of pure components over a wide range of states. However, modeling mixture diffusion coefficients by entropy scaling is an unresolved task. We tackle this issue and present an entropy scaling framework for predicting mixture self-diffusion coefficients as well as mutual diffusion coefficients in a thermodynamically consistent way. The predictions of the mixture diffusion coefficients are made based on information on the self-diffusion coefficients of the pure components and the infinite-dilution diffusion coefficients. This is accomplished using information on the entropy of the mixture, which is taken here from molecular-based equations of state. Examples for the application of the entropy scaling framework for the prediction of diffusion coefficients in mixtures illustrate its performance. It enables predictions over a wide range of temperatures and pressures including gaseous, liquid, supercritical, and metastable states - also for strongly non-ideal mixtures.
Keywords
Cite
@article{arxiv.2409.17615,
title = {Entropy Scaling for Diffusion Coefficients in Fluid Mixtures},
author = {Sebastian Schmitt and Hans Hasse and Simon Stephan},
journal= {arXiv preprint arXiv:2409.17615},
year = {2026}
}