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Infinite-pressure phase diagram of binary mixtures of (non)additive hard disks

Etienne Fayen, Anuradha Jagannathan, Giuseppe Foffi, Frank Smallenburg

2020The Journal of Chemical Physics25 citationsDOIOpen Access PDF

Abstract

One versatile route to the creation of two-dimensional crystal structures on the nanometer to micrometer scale is the self-assembly of colloidal particles at an interface. Here, we explore the crystal phases that can be expected from the self-assembly of mixtures of spherical particles of two different sizes, which we map to (additive or non-additive) hard-disk mixtures. We map out the infinite-pressure phase diagram for these mixtures using Floppy Box Monte Carlo simulations to systematically sample candidate crystal structures with up to 12 disks in the unit cell. As a function of the size ratio and the number ratio of the two species of particles, we find a rich variety of periodic crystal structures. Additionally, we identify random tiling regions to predict random tiling quasicrystal stability ranges. Increasing non-additivity both gives rise to additional crystal phases and broadens the stability regime for crystal structures involving a large number of large-small contacts, including random tilings. Our results provide useful guidelines for controlling the self-assembly of colloidal particles at interfaces.

Topics & Concepts

Phase diagramQuasicrystalMaterials scienceMonte Carlo methodBinary numberCrystal (programming language)Phase (matter)Statistical physicsLiquid crystalColloidChemical physicsPhysicsCondensed matter physicsMathematicsChemistryComputer scienceArithmeticOptoelectronicsPhysical chemistryQuantum mechanicsStatisticsProgramming languagePickering emulsions and particle stabilizationMaterial Dynamics and PropertiesProteins in Food Systems
Infinite-pressure phase diagram of binary mixtures of (non)additive hard disks | Litcius