Journal article · Preprint article
Effect of charged line defects on conductivity in graphene: Numerical Kubo and analytical Boltzmann approaches
Institute for Metal Physics1
Department of Micro- and Nanotechnology, Technical University of Denmark2
Theoretical Nanotechnology, Department of Micro- and Nanotechnology, Technical University of Denmark3
Linköping University4
National University of Singapore5
Center for Nanostructured Graphene, Centers, Technical University of Denmark6
Charge carrier transport in single-layer graphene with one-dimensional charged defects is studied theoretically. Extended charged defects, considered an important factor for mobility degradation in chemically vapor-deposited graphene, are described by a self-consistent Thomas-Fermi potential. A numerical study of electronic transport is performed by means of a time-dependent real-space Kubo approach in honeycomb lattices containing millions of carbon atoms, capturing the linear response of realistic size systems in the highly disordered regime.
Our numerical calculations are complemented with a kinetic transport theory describing charge transport in the weak scattering limit. The semiclassical transport lifetimes are obtained by computing scattered amplitudes within the second Born approximation. The transport electron-hole asymmetry found in the semiclassical approach is consistent with the Kubo calculations.
In the strong scattering regime, the conductivity is found to be a sublinear function of electronic density and weakly dependent on the Thomas-Fermi screening wavelength. We attribute this atypical behavior to the extended nature of one-dimensional charged defects. Our results are consistent with recent experimental reports.
| Language: | English |
|---|---|
| Year: | 2013 |
| Pages: | 15 |
| ISSN: | 1550235x , 10980121 and 01631829 |
| Types: | Journal article and Preprint article |
| DOI: | 10.1103/PhysRevB.87.195448 |
