Physics – Condensed Matter – Materials Science
Scientific paper
2008-10-03
Physics
Condensed Matter
Materials Science
Scientific paper
We present density functional theory (DFT) based non-equilibrium Green's function (NEGF) calculations for the conductance through a nitrobenzene molecule, which is anchored by pyridil-groups to Au electrodes. This work is building up on earlier theoretical studies where quantum interference effects (QIE) have been identified both in qualitative tight binding and in DFT descriptions for the same molecule with different chemical connections to the leads. The novelty in the current contribution is two-fold: i) The pyridil-anchors guarantee for the conductance to be determined by rather narrow peaks situated closely to the Fermi energy which is relevant because it might maximize the impact of quantum interferences on the I/V behaviour. In a scan of eight different junction setups, where the connection sites of aromatic rings, their torsion angle with respect to each other and the surface structure have been varied, QIE was found to dominate the conductance for only one planar geometry. For finite torsion angles between aromatic rings the effect moves to higher energies and would therefore only be accessible for experimental observation in a gated junction. ii) A detailed comparison between simple topological models and DFT results for the investigated systems aims at assessing the usefulness of such models as analysis tools for a better understanding of the physics of QIE and its structure dependence.
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