Entropic patchiness drives multiphase coexistence in discotic colloid–depletant mixtures

A. González García, H.H. Wensink, H.N.W. Lekkerkerker, R. Tuinier

Research output: Contribution to journalArticleAcademicpeer-review

Abstract

Entropy–driven equilibrium phase behaviour of hard particle dispersions can be understood from excluded volume arguments only. While monodisperse hard spheres only exhibit a fluid–solid phase transition, anisotropic hard particles such as rods, discs, cuboids or boards exhibit various multi–phase equilibria. Ordering of such anisotropic particles increases the free volume entropy by reducing the excluded volume between them. The addition of depletants gives rise to an entropic patchiness represented by orientation–dependent attractions resulting in non–trivial phase behaviour. We show that free volume theory is a simple, generic and tractable framework that enables to incorporate these effects and rationalise various experimental findings. Plate-shaped particles constitute the main building blocks of clays, asphaltenes and chromonic liquid crystals that find widespread use in the food, cosmetics and oil industry. We demonstrate that mixtures of platelets and ideal depletants exhibit a strikingly rich phase behaviour containing several types of three–phase coexistence areas and even a quadruple region with four coexisting phases.
Original languageEnglish
Article number17058
Number of pages9
JournalScientific Reports
Volume7
DOIs
Publication statusPublished - 6 Dec 2017

Keywords

  • Condensed-matter physics
  • Thermodynamics

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