Vibrationally-mediated molecular transistors
Abstract
We investigate the steady-state electronic transport through a suspended dimer molecule coupled to leads. When strongly coupled to a vibrational mode, the electron transport is enhanced at the phonon resonant frequency and higher-order resonances. The temperature and bias determines the nature of the phonon-assisted resonances, with clear absorption and emission peaks. The strong coupling also induces a Frank-Condon-like blockade, suppressing the current between the resonances. We compare an analytical polaron transformation method to two exact numerical methods: the Hierarchy equations of motion and an exact diagonalization in the Fock basis. In the steady--state, our two numerical results are an exact match and qualitatively reflect the main features of the polaron treatment. Our results indicate the possibility of a new type of molecular transistor or sensor where the current can be extremely sensitive to small changes in the energies of the electronic states in the dimer.
Cite
@article{arxiv.1210.7098,
title = {Vibrationally-mediated molecular transistors},
author = {D. H. Santamore and Neill Lambert and Franco Nori},
journal= {arXiv preprint arXiv:1210.7098},
year = {2013}
}
Comments
11 pages, 7 figures