Tohru Kawarabayashi, Yasuhiro Hatsugai, Hideo Aoki
Published 2009-04-13, updated 2009-09-17Version 2
We investigate how the criticality of the quantum Hall plateau transition in disordered graphene differs from those in the ordinary quantum Hall systems, based on the honeycomb lattice with ripples modeled as random hoppings. The criticality of the graphene-specific n=0 Landau level is found to change dramatically to an anomalous, almost exact fixed point as soon as we make the random hopping spatially correlated over a few bond lengths. We attribute this to the preserved chiral symmetry and suppressed scattering between K and K' points in the Brillouin zone. The results suggest that a fixed point for random Dirac fermions with chiral symmetry can be realized in free-standing, clean graphene with ripples.
Comments: 5 pages, 4 figures, changes in figure 2
Journal: Phys. Rev. Lett. 103, 156804 (2009)
Anomalous criticality in the quantum Hall transition at $n=0$ Landau level of graphene with chiral-symmetric disorders
Transport via classical percolation at quantum Hall plateau transitions
Conductance fluctuations at the quantum Hall plateau transition
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