Volume 210, 2018

Charge transport at a molecular GaAs nanoscale junction

Abstract

In recent years, the use of non-metallic electrodes for the fabrication of single-molecule junctions has developed into an elegant way to impart new properties to nanodevices. Integration of molecular junctions in a semiconducting platform would also speed technological deployment, as it would take advantage of established industrial infrastructures. In a previous proof-of-concept paper, we used simple α,ω-dithiol self-assembled monolayers on a gallium arsenide (GaAs) substrate to fabricate molecular Schottky diodes with a STM. In the devices, we were also able to detect the contribution of a single-molecule to the overall charge transport. The prepared devices can also be used as photodiodes, as GaAs is a III–V direct bandgap (1.42 eV at room temperature) semiconductor, and it efficiently absorbs visible light to generate a photocurrent. In this contribution, we demonstrate that fine control can be exerted on the electrical behaviour of a metal-molecule–GaAs junction by systematically altering the nature of the molecular bridge, the type and doping density of the semiconductor and the light intensity and wavelength. Molecular orbital energy alignment dominates the charge transport properties, resulting in strongly rectifying junctions prepared with saturated bridges (e.g. alkanedithiols), with increasingly ohmic characteristics as the degree of saturation is reduced through the introduction of conjugated moieties. The effects we observed are local, and may be observed with electrodes of only a few tens of nanometres in size, hence paving the way to the use of semiconducting nanoelectrodes to probe molecular properties. Perspectives of these new developments for single molecule semiconductor electrochemistry are also discussed.

Graphical abstract: Charge transport at a molecular GaAs nanoscale junction

Associated articles

Article information

Article type
Paper
Submitted
05 feb. 2018
Accepted
12 feb. 2018
First published
15 feb. 2018
This article is Open Access
Creative Commons BY license

Faraday Discuss., 2018,210, 397-408

Charge transport at a molecular GaAs nanoscale junction

A. Vezzoli, R. J. Brooke, N. Ferri, C. Brooke, S. J. Higgins, W. Schwarzacher and R. J. Nichols, Faraday Discuss., 2018, 210, 397 DOI: 10.1039/C8FD00016F

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