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Electrostatic control over temperature-dependent tunnelling across a single-molecule junction.


ABSTRACT: Understanding how the mechanism of charge transport through molecular tunnel junctions depends on temperature is crucial to control electronic function in molecular electronic devices. With just a few systems investigated as a function of bias and temperature so far, thermal effects in molecular tunnel junctions remain poorly understood. Here we report a detailed charge transport study of an individual redox-active ferrocene-based molecule over a wide range of temperatures and applied potentials. The results show the temperature dependence of the current to vary strongly as a function of the gate voltage. Specifically, the current across the molecule exponentially increases in the Coulomb blockade regime and decreases at the charge degeneracy points, while remaining temperature-independent at resonance. Our observations can be well accounted for by a formal single-level tunnelling model where the temperature dependence relies on the thermal broadening of the Fermi distributions of the electrons in the leads.

SUBMITTER: Garrigues AR 

PROVIDER: S-EPMC4879245 | biostudies-literature | 2016 May

REPOSITORIES: biostudies-literature

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Electrostatic control over temperature-dependent tunnelling across a single-molecule junction.

Garrigues Alvar R AR   Wang Lejia L   Del Barco Enrique E   Nijhuis Christian A CA  

Nature communications 20160523


Understanding how the mechanism of charge transport through molecular tunnel junctions depends on temperature is crucial to control electronic function in molecular electronic devices. With just a few systems investigated as a function of bias and temperature so far, thermal effects in molecular tunnel junctions remain poorly understood. Here we report a detailed charge transport study of an individual redox-active ferrocene-based molecule over a wide range of temperatures and applied potentials  ...[more]

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