https://orcid.org/0000-0002-6806-644X
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Abstract
The electron transport through the single-molecule junction of benzene-1,4-diamine (BDA) is modelled using ab initio quantum-classical molecular dynamics of electron attached states. Observations on the nature of the process are made by time-resolved analysis of energy differences, non-adiabatic transition probabilities and the spatial distribution of the excess electron. The role of molecular vibrations that facilitate the transport by being responsible for the periodic behaviour of these quantities is shown using normal mode analysis. The results support a mechanism involving the electron's direct hopping between the electrodes, without its presence on the molecule, with the prime importance of the bending vibrations that periodically alter the molecule–electrode interactions. No relevant differences are found between results provided by the ADC(2) and SOS-ADC(2) excited state models. Our approach provides an alternative insight into the role of nuclear motions in the electron transport process, one which is more expressive from the chemical perspective.
GRAPHICAL ABSTRACT
Acknowledgments
With this paper AT and PGS would like to thank Prof. John Stanton for his friendship and long lasting fruitful collaboration. The authors appreciate the computational resources provided by the ELTE IIG High-Performance Computing facility.
Disclosure statement
No potential conflict of interest was reported by the author(s).