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      Gating of single molecule junction conductance by charge transfer complex formation

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          Abstract

          Tetracyanoethene complexation boosts the conductance of metal |molecule| metal single molecule junctions involving suitable aromatic donor moieties by about 20-fold.

          Abstract

          The solid-state structures of organic charge transfer (CT) salts are critical in determining their mode of charge transport, and hence their unusual electrical properties, which range from semiconducting through metallic to superconducting. In contrast, using both theory and experiment, we show here that the conductance of metal |single molecule| metal junctions involving aromatic donor moieties (dialkylterthiophene, dialkylbenzene) increase by over an order of magnitude upon formation of charge transfer (CT) complexes with tetracyanoethylene (TCNE). This enhancement occurs because CT complex formation creates a new resonance in the transmission function, close to the metal contact Fermi energy, that is a signal of room-temperature quantum interference.

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          Measurement of single-molecule resistance by repeated formation of molecular junctions.

          Bingqian Xu, Nongjian Tao (2003)
          The conductance of a single molecule connected to two gold electrodes was determined by repeatedly forming thousands of gold-molecule-gold junctions. Conductance histograms revealed well-defined peaks at integer multiples of a fundamental conductance value, which was used to identify the conductance of a single molecule. The resistances near zero bias were 10.5 +/- 0.5, 51 +/- 5, 630 +/- 50, and 1.3 +/- 0.1 megohms for hexanedithiol, octanedithiol, decanedithiol, and 4,4' bipyridine, respectively. The tunneling decay constant (betaN) for N-alkanedithiols was 1.0 +/- 0.1 per carbon atom and was weakly dependent on the applied bias. The resistance and betaN values are consistent with first-principles calculations.
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            Superconductivity in a synthetic organic conductor (TMTSF)2PF 6

            D. Jérome, A. Mazaud, M Ribault (1980)
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              Electron transport in molecular junctions.

              N J Tao (2006)
              Building an electronic device using individual molecules is one of the ultimate goals in nanotechnology. To achieve this it will be necessary to measure, control and understand electron transport through molecules attached to electrodes. Substantial progress has been made over the past decade and we present here an overview of some of the recent advances. Topics covered include molecular wires, two-terminal switches and diodes, three-terminal transistor-like devices and hybrid devices that use various different signals (light, magnetic fields, and chemical and mechanical signals) to control electron transport in molecules. We also discuss further issues, including molecule-electrode contacts, local heating- and current-induced instabilities, stochastic fluctuations and the development of characterization tools.
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                Author and article information

                Journal
                Journal ID (publisher-id): NANOHL
                Title: Nanoscale
                Abbreviated Title: Nanoscale
                Publisher: Royal Society of Chemistry (RSC)
                ISSN (Print): 2040-3364
                ISSN (Electronic): 2040-3372
                Publication date Created: 2015
                Publication date (Electronic): 2015
                Volume: 7
                Issue: 45
                Pages: 18949-18955
                Affiliations
                [1 ]Department of Chemistry
                [2 ]Donnan and Robert Robinson Laboratories
                [3 ]University of Liverpool
                [4 ]Liverpool L69 7ZD, UK
                [5 ]Department of Physics
                [6 ]Lancaster University
                [7 ]Lancaster LA1 4YB, UK
                [8 ]College of Engineering & NanoSEC
                [9 ]University of Georgia
                [10 ]Athens, USA
                Article
                DOI: 10.1039/C5NR04420K
                SO-VID: 02331ce1-b47d-4fb4-9f7a-8c1536aea224
                Copyright © © 2015
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