Phase-space for the breakdown of the quantum Hall effect in epitaxial graphene

Abstract

We report the phase-space defined by the quantum Hall effect breakdown in polymer gated epitaxial graphene on SiC (SiC/G) as a function of temperature, current, carrier density, and magnetic fields up to 30T. At 2K breakdown currents (Ic) almost two orders of magnitude greater than in GaAs devices are observed. The phase boundary of the dissipationless state (xx=0) shows a (1-(T/Tc)2) dependence and persists up to Tc>45K at 29T. With magnetic field Ic was found to increase B3/2 and Tc B1.88. As the Fermi energy approaches the Dirac point, the =2 quantized Hall plateau appears continuously from fields as low as 1T up to at least 19T due to a strong magnetic field dependence of the carrier density.