A reliable method has been developed for making through-bond electrical contacts to molecules. Current-voltage curves are quantized as integer multiples of one fundamental curve, an observation used to identify single-molecule contacts. The resistance of a single octanedithiol molecule was 900 +/- 50 megohms, based on measurements on more than 1000 single molecules. In contrast, nonbonded contacts to octanethiol monolayers were at least four orders of magnitude more resistive, less reproducible, and had a different voltage dependence, demonstrating that the measurement of intrinsic molecular properties requires chemically bonded contacts.
We compile, compare, and discuss experimental results on low‐bias, room‐temperature currents through organic molecules obtained in different electrode–molecule–electrode test‐beds. Currents are normalized to single‐molecule values for comparison and are quoted at 0.2 and 0.5 V junction bias. Emphasis is on currents through saturated alkane chains where many comparable measurements have been reported, but comparison to conjugated molecules is also made. We discuss factors that affect the magnitude of the measured current, such as tunneling attenuation factor, molecular energy gap and conformation, molecule/electrode contacts, and electrode material.
Electrical contacts between a metal probe and molecular
monolayers have been characterized using conducting atomic force
microscopy in an inert environment and in a voltage range that yields
reversible current-voltage data. The current through alkanethiol
monolayers depends on the contact force in a way that is accounted for by
the change of chain-to-chain tunnelling with film thickness. The
electronic decay constant, βN, was obtained from
measurements as a function of chain length at constant force and
bias, yielding βN = 0.8±0.2 per methylene over a
±3 V range. Current-voltage curves are difficult to reconcile
with this almost constant value. Very different results are obtained
when a gold tip contacts a 1,8-octanedithiol film. Notably, the
current-voltage curves are often independent of contact
force. Thus the contact may play a critical role both in the nature
of charge transport and the shape of the current-voltage curve.
Molecular electronic devices require at least two electrical contacts to one (or more) molecule(s). Single molecules are reliably probed by bonding one end to a gold substrate and the other end to a gold nanocrystal. The circuit is completed with a gold-coated atomic force microscope probe. Measurements of the decay of electronic current with the length of n-alkanedithiol molecules in these single-molecule nanojunctions are reported as a function of the applied bias. The value of the decay constant near zero bias was obtained from measurements in the ohmic region of the current-voltage curves. The electron tunneling decay rate is significantly smaller (β N ) 0.57 ( 0.03) than observed for molecules bonded at just one end (β N ≈ 1), and it falls to even smaller values as the applied bias is increased. Both these effects are quantitatively accounted for by a large shift in molecular levels caused by the attachment of wires at each end.
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