2012
DOI: 10.1073/pnas.1201557109
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Charge transport in molecular electronic junctions: Compression of the molecular tunnel barrier in the strong coupling regime

Abstract: Molecular junctions are essentially modified electrodes familiar to electrochemists where the electrolyte is replaced by a conducting "contact." It is generally hypothesized that changing molecular structure will alter system energy levels leading to a change in the transport barrier. Here, we show the conductance of seven different aromatic molecules covalently bonded to carbon implies a modest range (<0.5 eV) in the observed transport barrier despite widely different free molecule HOMO energies (>2 eV range)… Show more

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Cited by 143 publications
(289 citation statements)
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“…The values of β for d < 8 nm agree well with the 2-4 nm −1 values reported for other aromatic molecules for this range of thickness (13,14). Note that extrapolation of the ln J vs. d plot in the β = 3 nm −1 region to d >8 nm (shown by the dashed line in Fig.…”
Section: Resultssupporting
confidence: 76%
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“…The values of β for d < 8 nm agree well with the 2-4 nm −1 values reported for other aromatic molecules for this range of thickness (13,14). Note that extrapolation of the ln J vs. d plot in the β = 3 nm −1 region to d >8 nm (shown by the dashed line in Fig.…”
Section: Resultssupporting
confidence: 76%
“…For d < 8 nm, current is controlled by coherent tunneling, with minimal temperature dependence and β = 3 nm −1 , as described previously for conjugated molecular junctions (9,14,30). For low field and high T, the thickest devices (d > 16 nm) exhibit hopping transport with β < 0.1 nm −1 and strong T dependence, similar to that observed for bulk organic semiconductors.…”
Section: Discussionmentioning
confidence: 81%
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“…[1][2][3][4] As a consequence, electronic energy level alignment at interfaces between organic components (such as individual molecules) and inorganic electrodes, which are critical to charge flow within organic devices, have been the focus of significant recent fundamental work [5][6][7][8][9][10][11][12][13]. When a molecule is in contact with an electrode, its orbital energies are significantly altered relative to the gas-phase by several competing physical contributions.…”
mentioning
confidence: 99%