Physics – Condensed Matter – Materials Science
Scientific paper
2008-06-20
Physics
Condensed Matter
Materials Science
6 pages, 5 figures
Scientific paper
We present a qualitative model for a fundamental process in molecular electronics: the change in conductance upon bond breaking. In our model a diatomic molecule is attached to spin-polarized contacts. Employing a Hubbard Hamiltonian, electron interaction is neglected in the contacts and explicitly considered in the molecule, enabling us to study the impact of electron interaction on the molecular conductance. In the limit where the electron repulsion is strong compared to the binding energy (as it becomes the case upon dissociation) electron transmission in strongly suppressed compared to the non-interacting case. However, the spin-polarized nature of the contacts introduces a coupling between the molecular singlet and triplet states. This coupling in turn yields additional resonances in the transmission probability that significantly reduce the energetic separation appear between resonances. The ramifications of our results on transport experiments performed on nanowires with inclusions $H_2$ are discussed.
Ernzerhof Matthias
Goker Ali
Goyer Francois
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