Ivan A. Pshenichnyuk, Pedro B. Coto, Susanne Leitherer, Michael Thoss
Published 2012-12-16, updated 2013-02-25Version 2
We investigate charge transport in pentacene-graphene nanojunctions employing density functional theory (DFT) electronic structure calculations and the Landauer transport formalism. The results show that the unique electronic properties of graphene strongly influence the transport in the nanojunctions. In particular, edge states in graphene electrodes with zigzag termination result in additional transport channels close to the Fermi energy which deeply affects the conductance at small bias voltages. Investigating different linker groups as well as chemical substitution, we demonstrate how the transport properties are furthermore influenced by the molecule-lead coupling and the energy level lineup.
Charge transport through graphene junctions with wetting metal leads
Spin and charge transport in material with spin-dependent conductivity
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