Intrinsic and Extrinsic Performance Limits of Graphene Devices on SiO2

Abstract

The linear dispersion relation in graphene[1,2] gives rise to a surprising prediction: the resistivity due to isotropic scatterers (e.g. white-noise disorder[3] or phonons[4-8]) is independent of carrier density n. Here we show that acoustic phonon scattering[4-6] is indeed independent of n, and places an intrinsic limit on the resistivity in graphene of only 30 Ohm at room temperature (RT). At a technologically-relevant carrier density of 1012 cm-2, the mean free path for electron-acoustic phonon scattering is >2 microns, and the intrinsic mobility limit is 2x105 cm2/Vs, exceeding the highest known inorganic semiconductor (InSb, ~7.7x104 cm2/Vs[9]) and semiconducting carbon nanotubes (~1x105 cm2/Vs[10]). We also show that extrinsic scattering by surface phonons of the SiO2 substrate[11,12] adds a strong temperature dependent resistivity above ~200 K[8], limiting the RT mobility to ~4x104 cm2/Vs, pointing out the importance of substrate choice for graphene devices[13].