Quantum conductance of silicon-doped carbon wire nanojunctions
نویسندگان
چکیده
Unknown quantum electronic conductance across nanojunctions made of silicon-doped carbon wires between carbon leads is investigated. This is done by an appropriate generalization of the phase field matching theory for the multi-scattering processes of electronic excitations at the nanojunction and the use of the tight-binding method. Our calculations of the electronic band structures for carbon, silicon, and diatomic silicon carbide are matched with the available corresponding density functional theory results to optimize the required tight-binding parameters. Silicon and carbon atoms are treated on the same footing by characterizing each with their corresponding orbitals. Several types of nanojunctions are analyzed to sample their behavior under different atomic configurations. We calculate for each nanojunction the individual contributions to the quantum conductance for the propagating σ, Π, and σ∗electron incidents from the carbon leads. The calculated results show a number of remarkable features, which include the influence of the ordered periodic configurations of silicon-carbon pairs and the suppression of quantum conductance due to minimum substitutional disorder and artificially organized symmetry on these nanojunctions. Our results also demonstrate that the phase field matching theory is an efficient tool to treat the quantum conductance of complex molecular nanojunctions.
منابع مشابه
Theoretical and numerical modelling of electronic transport in nanostructures Modélisation théorique et numérique du transport électronique dans les nanostructures
Modélisation théorique et numérique du transportélectronique dans les nanostructures a thesis presented by Parts of this thesis have been previously published in: 1. Quantum conductance of silicon-doped carbon wire nanojunctions 3. A simple analytical model for electronic conductance in a one dimensional atomic chain across a defect Author of this thesis is also a co-author of other papers: 1. ...
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