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A new concept for a single molecule transistor is demonstrated. A single chargeable atom adjacent to a molecule shifts molecular energy levels into alignment with electrode levels, thereby gating current through the molecule. Seemingly paradoxically, the silicon substrate to which the molecule is covalently attached provides 2, not 1, effective contacts to the molecule. This is achieved because the single charged silicon atom is at a substantially different potential than the remainder of the substrate. Charge localization at one dangling bond is ensured by covalently capping all other surface atoms. Dopant level control and local Fermi level control can change the charge state of that atom. The same configuration is shown to be an effective transducer to an electrical signal of a single molecule detection event.
Because the charged atom induced shifting results in conductivity changes of substantial magnitude, these effects are easily observed at room temperature.
One electron is sufficient to achieve gating because high gate efficiency is achieved.
Because one electron achieves gating, compared to ~10^5 in a modern transistor, enormous speed, and minimal power consumption are implied.
Though enormous challenges must be overcome before this concept enables a new technology, it appears to be worth facing those challenges.
Researchers should cite this work as follows:
(2005), "Field Regulation of Single Molecule Conductivity by a Charged Atom," https://nanohub.org/resources/431.