Impact of graphene quantum capacitance on transport spectroscopy

Abstract

We demonstrate experimentally that graphene quantum capacitance Cq can have a strong impact on transport spectroscopy through the interplay with nearby charge reservoirs. The effect is elucidated in a field-effect-gated epitaxial graphene device, in which interface states serve as charge reservoirs. The Fermi-level dependence of Cq is manifested as an unusual parabolic gate voltage (Vg) dependence of the carrier density, centered on the Dirac point. Consequently, in high magnetic fields B, the spectroscopy of longitudinal resistance (Rxx) vs. Vg represents the structure of the unequally spaced relativistic graphene Landau levels (LLs). Rxx mapping vs. Vg and B thus reveals the vital role of the zero-energy LL on the development of the anomalously wide =2 quantum Hall state.