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Simulating self-assembly of ZnS nanoparticles into mesoporous materials

Sayle, D.C., Mangili, B.C., Klinowski, J., Sayle, T.X.T. (2006) Simulating self-assembly of ZnS nanoparticles into mesoporous materials. Journal of the American Chemical Society, 128 (47). pp. 15283-15291. ISSN 00027863 (ISSN). (doi:10.1021/ja0650697) (The full text of this publication is not currently available from this repository. You may be able to access a copy if URLs are provided) (KAR id:46795)

The full text of this publication is not currently available from this repository. You may be able to access a copy if URLs are provided.
Official URL:
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Abstract

Characterization of materials is crucial for the quantification and prediction of their physical, chemical, and mechanical properties. However, as the complexity of a system increases, so do the challenges involved in elucidating its structure. While molecular simulation and modeling have proved invaluable as complements to experiment, such simulations now face serious challenges: new materials are being synthesized with ever increasing structural complexity, and it may soon prove impossible to generate models that are sufficiently realistic to describe them adequately. Perhaps, ultimately, it will only be possible to generate such models by simulating the synthetic process itself. Here, we attempt such a strategy to generate full atomistic models for mesoporous molecular sieves. As in experiment, this is done by allowing nanoparticles to self-assemble at high temperature to form an amorphous mesoporous framework. The temperature is then reduced, and the system is allowed to crystallize. Animations of atomic trajectories, available as Supporting Information, reveal the evolution of multiple seeds which propagate to form a complex framework. The products are polycrystalline mesoporous framework structures containing cavities connected by channels running along "zero", one, two, and three perpendicular directions. We suggest that it is easier to generate these model structures by attempting to simulate the synthetic process rather than by using more conventional techniques. The strategy is illustrated using ZnS as a model system. Further development of the mathematics of minimal surfaces will advance our understanding of these structures. © 2006 American Chemical Society.

Item Type: Article
DOI/Identification number: 10.1021/ja0650697
Additional information: Unmapped bibliographic data: LA - English [Field not mapped to EPrints] J2 - J. Am. Chem. Soc. [Field not mapped to EPrints] AD - DEOS, Cranfield University, Defence Academy of the United Kingdom, Shrivenham, Swindon SN6 8LA, United Kingdom [Field not mapped to EPrints] AD - Department of Chemistry, University of Cambridge, Lensfield Road, Cambridge CB2 1EW, United Kingdom [Field not mapped to EPrints] DB - Scopus [Field not mapped to EPrints]
Uncontrolled keywords: Complexation, Composition, Computer simulation, Mesoporous materials, Molecular structure, Self assembly, Zinc sulfide, Cavities, Molecular simulations, Structural complexity, Nanostructured materials, zinc sulfide, article, atom, chemical analysis, chemical structure, crystallization, materials, materials testing, mechanics, molecular model, molecule, nanoparticle, physical chemistry, prediction, quantitative analysis, simulation, structure analysis, synthesis, temperature
Subjects: Q Science
Divisions: Divisions > Division of Natural Sciences > Physics and Astronomy
Depositing User: Dean Sayle
Date Deposited: 06 Mar 2015 16:28 UTC
Last Modified: 16 Nov 2021 10:18 UTC
Resource URI: https://kar.kent.ac.uk/id/eprint/46795 (The current URI for this page, for reference purposes)

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