Erpenbeck A, Haertle R, Bockstedte MG, Thoss M (2016)
Publication Type: Journal article
Publication year: 2016
Publisher: American Physical Society
Book Volume: 93
Pages Range: 115421
Journal Issue: 11
URI: http://link.aps.org/doi/10.1103/PhysRevB.93.115421
DOI: 10.1103/PhysRevB.93.115421
We investigate the role of electronic-vibrational coupling in resonant electron transport through single-molecule junctions, taking into account that the corresponding coupling strengths may depend on the charge and excitation state of the molecular bridge. Within an effective-model Hamiltonian approach for a molecule with multiple electronic states, this requires to extend the commonly used model and include vibrationally dependent electron-electron interaction. We use Born-Markov master equation methods and consider selected models to exemplify the effect of the additional interaction on the transport characteristics of a single-molecule junction. In particular, we show that it has a significant influence on local cooling and heating mechanisms, it may result in negative differential resistance, and it may cause pronounced asymmetries in the conductance map of a single-molecule junction.
APA:
Erpenbeck, A., Haertle, R., Bockstedte, M.G., & Thoss, M. (2016). Vibrationally dependent electron-electron interactions in resonant electron transport through single-molecule junctions. Physical Review B, 93(11), 115421. https://doi.org/10.1103/PhysRevB.93.115421
MLA:
Erpenbeck, André, et al. "Vibrationally dependent electron-electron interactions in resonant electron transport through single-molecule junctions." Physical Review B 93.11 (2016): 115421.
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