Energy Relaxation of Hot Dirac Fermions in Graphene

Abstract

We develop a theory for the energy relaxation of hot Dirac fermions in graphene. We obtain a generic expression for the energy relaxation rate due to electron-phonon interaction and calculate the power loss due to both optical and acoustic phonon emission as a function of electron temperature Te and density n. We find an intrinsic power loss weakly dependent on carrier density and non-vanishing at the Dirac point n = 0, originating from interband electron-optical phonon scattering by the intrinsic electrons in the graphene valence band. We obtain the total power loss per carrier 10-12 - 10-7 W within the range of electron temperatures 20 - 1000 K. We find optical (acoustic) phonon emission to dominate the energy loss for Te > (<) 200-300 K in the density range n = 1011-1013 cm-2.