Molecular simulations of self-assembling bio-inspired supramolecular systems and their connection to experiments

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82 Citaten (Scopus)
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Samenvatting

In bionanotechnology, the field of creating functional materials consisting of bio-inspired molecules, the function and shape of a nanostructure only appear through the assembly of many small molecules together. The large number of building blocks required to define a nanostructure combined with the many degrees of freedom in packing small molecules has long precluded molecular simulations, but recent advances in computational hardware as well as software have made classical simulations available to this strongly expanding field. Here, we review the state of the art in simulations of self-assembling bio-inspired supramolecular systems. We will first discuss progress in force fields, simulation protocols and enhanced sampling techniques using recent examples. Secondly, we will focus on efforts to enable the comparison of experimentally accessible observables and computational results. Experimental quantities that can be measured by microscopy, spectroscopy and scattering can be linked to simulation output either directly or indirectly, via quantum mechanical or semi-empirical techniques. Overall, we aim to provide an overview of the various computational approaches to understand not only the molecular architecture of nanostructures, but also the mechanism of their formation.

Originele taal-2English
Pagina's (van-tot)3470-3489
Aantal pagina's20
TijdschriftChemical Society Reviews
Volume47
Nummer van het tijdschrift10
Vroegere onlinedatum24-apr.-2018
DOI's
StatusPublished - 21-mei-2018

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