The electronic thickness of graphene

Authors :: Peter Rickhaus
Kenji Watanabe
Ming-Hao Liu
Thomas Ihn
Marius Eich
Yongjin Lee
Riccardo Pisoni
Takashi Taniguchi
Annika Kurzmann
Klaus Richter
Hiske Overweg
Marcin Kurpas
Klaus Ensslin
Source :: Science Advances, Science Advances, 6 (11)
Publication Year :: 2020
Publisher :: American Association for the Advancement of Science (AAAS), 2020.
Abstract: When two dimensional crystals are atomically close, their finite thickness becomes relevant. Using transport measurements, we investigate the electrostatics of two graphene layers, twisted by θ = 22° such that the layers are decoupled by the huge momentum mismatch between the K and K′ points of the two layers. We observe a splitting of the zero-density lines of the two layers with increasing interlayer energy difference. This splitting is given by the ratio of single-layer quantum capacitance over interlayer capacitance Cm and is therefore suited to extract Cm. We explain the large observed value of Cm by considering the finite dielectric thickness dg of each graphene layer and determine dg ≈ 2.6 Å. In a second experiment, we map out the entire density range with a Fabry-Pérot resonator. We can precisely measure the Fermi wavelength λ in each layer, showing that the layers are decoupled. Our findings are reproduced using tight-binding calculations.<br />Science Advances, 6 (11)<br />ISSN:2375-2548