Molecular bridging of silicon nanogaps

Ashwell, Geoffrey J.; Phillips, Laurie J.; Robinson, Benjamin J.; Lambert, Colin J.; Grace, Iain M.; Bryce, Martin R.; Sage, Ian C.; Tuffin, Rachel P.; Cox, Timothy; Urasinska-Wojcik, Barbara; Jitchati, Rukkiat; Tavasli, Mustafa; Ray, Shona

doi:10.1021/nn102460z

Molecular bridging of silicon nanogaps

Ashwell, Geoffrey J.; Phillips, Laurie J.; Robinson, Benjamin J.; Lambert, Colin J.; Grace, Iain M.; Bryce, Martin R.; Sage, Ian C.; Tuffin, Rachel P.; Cox, Timothy; Urasinska-Wojcik, Barbara; Jitchati, Rukkiat; Tavasli, Mustafa; Ray, Shona

Authors

Geoffrey J. Ashwell

Laurie J. Phillips

Benjamin J. Robinson

Colin J. Lambert

Iain M. Grace

Martin R. Bryce

Ian C. Sage

Rachel P. Tuffin

Dr Timothy Cox Timothy.Cox@uwe.ac.uk
Research Director

Barbara Urasinska-Wojcik

Rukkiat Jitchati

Mustafa Tavasli

Shona Ray

Abstract

The highly doped electrodes of a vertical silicon nanogap device have been bridged by a 5.85 nm long molecular wire, which was synthesized in situ by grafting 4-ethynylbenzaldehyde via C-Si links to the top and bottom electrodes and thereafter by coupling an amino-terminated fluorene unit to the aldehyde groups of the activated electrode surfaces. The number of bridging molecules is constrained by relying on surface roughness to match the 5.85 nm length with an electrode gap that is nominally 1 nm wider and may be controlled by varying the reaction time: the device current increases from ≤1 pA at 1 V following the initial grafting step to 10-100 nA at 1 V when reacted for 5-15 min with the amino-terminated linker and 10 μA when reacted for 16-53 h. It is the first time that both ends of a molecular wire have been directly grafted to silicon electrodes, and these molecule-induced changes are reversible. The bridges detach when the device is rinsed with dilute acid solution, which breaks the imine links of the in situ formed wire and causes the current to revert to the subpicoampere leakage value of the 4-ethynylbenzaldehyde-grafted nanogap structure. © 2010 American Chemical Society.

Journal Article Type	Article
Publication Date	Dec 28, 2010
Deposit Date	Oct 3, 2012
Journal	ACS Nano
Print ISSN	1936-0851
Electronic ISSN	1936-086X
Publisher	American Chemical Society
Peer Reviewed	Peer Reviewed
Volume	4
Issue	12
Pages	7401-7406
DOI	https://doi.org/10.1021/nn102460z
Keywords	molecular bridging, silicon, nanogaps
Public URL	https://uwe-repository.worktribe.com/output/982935
Publisher URL	http://dx.doi.org/10.1021/nn102460z
Contract Date	Apr 22, 2016

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Molecular bridging of silicon nanogaps

Ashwell, Geoffrey J.; Phillips, Laurie J.; Robinson, Benjamin J.; Lambert, Colin J.; Grace, Iain M.; Bryce, Martin R.; Sage, Ian C.; Tuffin, Rachel P.; Cox, Timothy; Urasinska-Wojcik, Barbara; Jitchati, Rukkiat; Tavasli, Mustafa; Ray, Shona

Authors

Abstract

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