arXiv:1502.07050 Abstract | arXiv Analytics

arXiv:1502.07050 [cond-mat.mes-hall]Abstract References Reviews Resources

Electronic Structure and Transport in Graphene/Haeckelite Hybrids: An {\em Ab Initio} Study

Zhen Zhu, Zacharias G. Fthenakis, David Tomanek

Published 2015-02-25Version 1

We combine {\em ab initio} density functional theory (DFT) structural studies with DFT-based nonequilibrium Green function calculations to investigate how the presence of non-hexagonal rings affects electronic transport in graphitic structures. We find that infinite monolayers, finite-width nanoribbons and nanotubes formed of 5-8 haeckelite with only 5- and 8-membered rings are generally more conductive than their graphene-based counterparts. Presence of haeckelite defect lines in the perfect graphitic structure, a model of grain boundaries in CVD-grown graphene, increases the electronic conductivity and renders it highly anisotropic.

Comments: 6 figures

Categories: cond-mat.mes-hall

Keywords: ab initio, graphene/haeckelite hybrids, electronic structure, non-hexagonal rings affects electronic transport, dft-based nonequilibrium green function calculations

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