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Predicting Spontaneous Orientational Self-Assembly: <i>In Silico</i> Design of Materials with Quantum Mechanically Derived Force Fields

Giacomo Prampolini, Leandro Greff da Silveira, J. G. Vilhena, Paolo R. Livotto

2021The Journal of Physical Chemistry Letters24 citationsDOI

Abstract

design of self-assembled materials hinges upon our ability to relate macroscopic properties to individual building blocks, thus characterizing in such supramolecular architectures a wide range of observables at varied time/length scales. This work demonstrates that quantum mechanical derived force fields (QMD-FFs) do satisfy this requisite and, most importantly, do so in a predictive manner. To this end, a specific FF, built solely based on the knowledge of the target molecular structure, is employed to reproduce the spontaneous transition to an ordered liquid crystal phase. The simulations deliver a multiscale portrait of such self-assembly processes, where conformational changes within the individual building blocks are intertwined with a 200 ns ensemble reorganization. The extensive characterization provided not only is in quantitative agreement with the experiment but also connects the time/length scales at which it was performed. Realizing QMD-FF predictive power and unmatched accuracy stands as an important leap forward for the bottom-up design of advanced supramolecular materials.

Topics & Concepts

QuantumSupramolecular chemistryObservableCharacterization (materials science)Work (physics)Materials scienceNanotechnologySupramolecular assemblyForce field (fiction)Computer scienceStatistical physicsChemical physicsPhysicsCrystal structureChemistryCrystallographyArtificial intelligenceQuantum mechanicsMaterial Dynamics and PropertiesSpectroscopy and Quantum Chemical StudiesSupramolecular Self-Assembly in Materials
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