Electrostatic Self-Assembly: Understanding the Significance of the Solvent

Eric B. Lindgren; Ivan N. Derbenev; Armik Khachatourian; Ho Kei Chan; Anthony J. Stace; Elena Besley

doi:10.1021/acs.jctc.7b00647

Electrostatic Self-Assembly: Understanding the Significance of the Solvent

Eric B. Lindgren
, Ivan N. Derbenev
, Armik Khachatourian
, Ho Kei Chan
, Anthony J. Stace
, Elena Besley^*

^*Corresponding author for this work

University of Nottingham
Troitsk Institute for Innovation and Fusion Research
California State University Los Angeles
Harbin Institute of Technology Shenzhen

Research output: Contribution to journal › Article › peer-review

46 Scopus citations

Abstract

The electrostatic deposition of particles has become a very effective route to the assembly of many nanoscale materials. However, fundamental limitations to the process are presented by the choice of solvent, which can either suppress or promote self-assembly depending on specific combinations of nanoparticle/surface/solvent properties. A new development in the theory of electrostatic interactions between polarizable objects provides insight into the effect a solvent can have on electrostatic self-assembly. Critical to assembly is the requirement for a minimum charge on a surface of an object, below which a solvent can suppress electrostatic attraction. Examples drawn from the literature are used to illustrate how switches in behavior are mediated by the solvent; these in turn provide a fundamental understanding of electrostatic particle-surface interactions applicable to many areas of materials science and nanotechnology.

Original language	English
Pages (from-to)	905-915
Number of pages	11
Journal	Journal of Chemical Theory and Computation
Volume	14
Issue number	2
DOIs	https://doi.org/10.1021/acs.jctc.7b00647
State	Published - 13 Feb 2018
Externally published	Yes

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title = "Electrostatic Self-Assembly: Understanding the Significance of the Solvent",

abstract = "The electrostatic deposition of particles has become a very effective route to the assembly of many nanoscale materials. However, fundamental limitations to the process are presented by the choice of solvent, which can either suppress or promote self-assembly depending on specific combinations of nanoparticle/surface/solvent properties. A new development in the theory of electrostatic interactions between polarizable objects provides insight into the effect a solvent can have on electrostatic self-assembly. Critical to assembly is the requirement for a minimum charge on a surface of an object, below which a solvent can suppress electrostatic attraction. Examples drawn from the literature are used to illustrate how switches in behavior are mediated by the solvent; these in turn provide a fundamental understanding of electrostatic particle-surface interactions applicable to many areas of materials science and nanotechnology.",

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AU - Stace, Anthony J.

AU - Besley, Elena

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AB - The electrostatic deposition of particles has become a very effective route to the assembly of many nanoscale materials. However, fundamental limitations to the process are presented by the choice of solvent, which can either suppress or promote self-assembly depending on specific combinations of nanoparticle/surface/solvent properties. A new development in the theory of electrostatic interactions between polarizable objects provides insight into the effect a solvent can have on electrostatic self-assembly. Critical to assembly is the requirement for a minimum charge on a surface of an object, below which a solvent can suppress electrostatic attraction. Examples drawn from the literature are used to illustrate how switches in behavior are mediated by the solvent; these in turn provide a fundamental understanding of electrostatic particle-surface interactions applicable to many areas of materials science and nanotechnology.

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Electrostatic Self-Assembly: Understanding the Significance of the Solvent

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