Litcius/Paper detail

Generating Cocrystal Polymorphs with Information Entropy Driven by Molecular Dynamics-Based Enhanced Sampling

H.K. Song, Leslie Vogt-Maranto, Ren A. Wiscons, Adam J. Matzger, Mark E. Tuckerman

2020The Journal of Physical Chemistry Letters49 citationsDOI

Abstract

Predicting structures of organic molecular cocrystals is a challenging task when considering the immense number of possible intermolecular orientations. Use of the Shannon information entropy, constructed from an intermolecular orientational spatial distribution function, to drive a search for crystal structures via enhanced molecular dynamics can be an efficient way to map out a landscape of putative polymorphs. Here, the Shannon entropy is used to generate a set of collective variables for differentiating polymorphs of a 1:1 cocrystal of resorcinol and urea. We show that driven adiabatic free energy dynamics, a particular enhanced-sampling approach, combined with these entropy variables, can transform the stable phase into alternate polymorphs. Density functional theory calculations confirm that a structure obtained from the enhanced molecular dynamics is stable at pressures above 1 GPa. We thus show that enhanced sampling should be considered an integral component of crystal structure searching protocols for systems with multiple independent molecules.

Topics & Concepts

CocrystalMolecular dynamicsCrystal structure predictionIntermolecular forceStatistical physicsEntropy (arrow of time)MoleculeChemical physicsEnergy landscapeDensity functional theoryCrystal structureComputational chemistryMaterials scienceChemistryThermodynamicsCrystallographyPhysicsHydrogen bondOrganic chemistryCrystallography and molecular interactionsComputational Drug Discovery MethodsProtein Structure and Dynamics
Generating Cocrystal Polymorphs with Information Entropy Driven by Molecular Dynamics-Based Enhanced Sampling | Litcius