English

Dirac-Kronig-Penney model for strain-engineered graphene

Mesoscale and Nanoscale Physics 2010-10-13 v2

Abstract

Motivated by recent proposals on strain-engineering of graphene electronic circuits we calculate conductivity, shot-noise and the density of states in periodically deformed graphene. We provide the solution to the Dirac-Kronig-Penney model, which describes the phase-coherent transport in clean monolayer samples with an one-dimensional modulation of the strain and the electrostatic potentials. We compare the exact results to a qualitative band-structure analysis. We find that periodic strains induce large pseudo-gaps and suppress charge transport in the direction of strain modulation. The strain-induced minima in the gate-voltage dependence of the conductivity characterize the quality of graphene superstructures. The effect is especially strong if the variation of inter-atomic distance exceeds the value a^2/l, where a is the lattice spacing of free graphene and l is the period of the superlattice. A similar effect induced by a periodic electrostatic potential is weakened due to Klein tunnelling.

Keywords

Cite

@article{arxiv.1006.3748,
  title  = {Dirac-Kronig-Penney model for strain-engineered graphene},
  author = {S. Gattenloehner and W. Belzig and M. Titov},
  journal= {arXiv preprint arXiv:1006.3748},
  year   = {2010}
}

Comments

11 pages, 8 figures

R2 v1 2026-06-21T15:38:17.378Z