Martina Flöser, Thierry Champel, Serge Florens
Published 2010-09-09, updated 2010-10-20Version 2
From the scattering of semicoherent-state wavepackets at high magnetic field, we derive analytically the transmission coefficient of electrons in graphene in the quantum Hall regime through a smooth constriction described by a quadratic saddle-point electrostatic potential. We find anomalous half-quantized conductance steps that are rounded by a backscattering amplitude related to the curvature of the potential. Furthermore, the conductance in graphene breaks particle-hole symmetry in cases where the saddle-point potential is itself asymmetric in space. These results have implications both for the interpretation of split-gate transport experiments, and for the derivation of quantum percolation models for graphene.
Comments: 4 pages, 2 figures Minor modifications as published
Journal: Phys. Rev. B 82,161408 (2010)
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