Litcius/Paper detail

Polymorphism and Perfection in Crystallization of Hard Sphere Polymers

Miguel Herranz, Katerina Foteinopoulou, Nikos Ch. Karayiannis, Manuel Laso

2022Polymers14 citationsDOIOpen Access PDF

Abstract

We present results on polymorphism and perfection, as observed in the spontaneous crystallization of freely jointed polymers of hard spheres, obtained in an unprecedentedly long Monte Carlo (MC) simulation on a system of 54 chains of 1000 monomers. Starting from a purely amorphous configuration, after an initial dominance of the hexagonal closed packed (HCP) polymorph and a transitory random hexagonal close packed (rHCP) morphology, the system crystallizes in a final, stable, face centered cubic (FCC) crystal of very high perfection. An analysis of chain conformational characteristics, of the spatial distribution of monomers and of the volume accessible to them shows that the phase transition is caused by an increase in translational entropy that is larger than the loss of conformational entropy of the chains in the crystal, compared to the amorphous state. In spite of the significant local re-arrangements, as reflected in the bending and torsion angle distributions, the average chain size remains unaltered during crystallization. Polymers in the crystal adopt ideal random walk statistics as their great length renders local conformational details, imposed by the geometry of the FCC crystal, irrelevant.

Topics & Concepts

CrystallizationAmorphous solidClose-packing of equal spheresConformational entropyMaterials scienceCrystallographyCrystal (programming language)PolymerPolymorphism (computer science)Hard spheresCrystal structureChemical physicsThermodynamicsChemistryPhysicsMoleculeComposite materialOrganic chemistryGenotypeGeneBiochemistryProgramming languageComputer sciencePolymer crystallization and propertiesMaterial Dynamics and PropertiesAdvanced Polymer Synthesis and Characterization
Polymorphism and Perfection in Crystallization of Hard Sphere Polymers | Litcius