Analysis of charge transport in arrays of 28 kDa nanocrystal gold molecules

Aidan J. Quinn; Matteo Biancardo; Liam Floyd; Maura Belloni; Peter R. Ashton; Jon A. Preece; Carlo A. Bignozzi; Gareth Redmond

doi:10.1039/b508404k

Analysis of charge transport in arrays of 28 kDa nanocrystal gold molecules

Aidan J. Quinn
, Matteo Biancardo
, Liam Floyd
, Maura Belloni
, Peter R. Ashton
, Jon A. Preece
, Carlo A. Bignozzi
, Gareth Redmond

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

Abstract

Arrays of 28 kDa nanocrystal gold molecules behave as weakly-coupled molecular solids comprising discrete nanoscale metallic islands separated by insulating ligand barriers. The key parameters which are found to dominate charge transport are (a) the single-electron nanocrystal charging energy, governed by the core diameter, the dielectric properties of the passivating ligands and classical electrostatic coupling between neighbouring cores; (b) the inter-nanocrystal tunnel barrier resistance that arises from the insulating nature of the ligand bilayers that separate the cores; and (c) the dimensionality of the network of current-carrying paths.

Original language	English
Pages (from-to)	4403-4407
Number of pages	5
Journal	Journal of Materials Chemistry
Volume	15
Issue number	41
DOIs	https://doi.org/10.1039/b508404k
Publication status	Published - 7 Nov 2005

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title = "Analysis of charge transport in arrays of 28 kDa nanocrystal gold molecules",

abstract = "Arrays of 28 kDa nanocrystal gold molecules behave as weakly-coupled molecular solids comprising discrete nanoscale metallic islands separated by insulating ligand barriers. The key parameters which are found to dominate charge transport are (a) the single-electron nanocrystal charging energy, governed by the core diameter, the dielectric properties of the passivating ligands and classical electrostatic coupling between neighbouring cores; (b) the inter-nanocrystal tunnel barrier resistance that arises from the insulating nature of the ligand bilayers that separate the cores; and (c) the dimensionality of the network of current-carrying paths.",

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AU - Quinn, Aidan J.

AU - Biancardo, Matteo

AU - Floyd, Liam

AU - Belloni, Maura

AU - Ashton, Peter R.

AU - Preece, Jon A.

AU - Bignozzi, Carlo A.

AU - Redmond, Gareth

PY - 2005/11/7

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N2 - Arrays of 28 kDa nanocrystal gold molecules behave as weakly-coupled molecular solids comprising discrete nanoscale metallic islands separated by insulating ligand barriers. The key parameters which are found to dominate charge transport are (a) the single-electron nanocrystal charging energy, governed by the core diameter, the dielectric properties of the passivating ligands and classical electrostatic coupling between neighbouring cores; (b) the inter-nanocrystal tunnel barrier resistance that arises from the insulating nature of the ligand bilayers that separate the cores; and (c) the dimensionality of the network of current-carrying paths.

AB - Arrays of 28 kDa nanocrystal gold molecules behave as weakly-coupled molecular solids comprising discrete nanoscale metallic islands separated by insulating ligand barriers. The key parameters which are found to dominate charge transport are (a) the single-electron nanocrystal charging energy, governed by the core diameter, the dielectric properties of the passivating ligands and classical electrostatic coupling between neighbouring cores; (b) the inter-nanocrystal tunnel barrier resistance that arises from the insulating nature of the ligand bilayers that separate the cores; and (c) the dimensionality of the network of current-carrying paths.

UR - https://www.scopus.com/pages/publications/27744492730

U2 - 10.1039/b508404k

DO - 10.1039/b508404k

M3 - Article

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VL - 15

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JO - Journal of Materials Chemistry

JF - Journal of Materials Chemistry

IS - 41

ER -

Analysis of charge transport in arrays of 28 kDa nanocrystal gold molecules

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