# Gate electrostatics and quantum capacitance in ballistic graphene   devices

**Authors:** Jos\'e M. Caridad, Stephen R. Power, Artsem A. Shylau, Lene, Gammelgaard, Antti-Pekka Jauho, Peter B{\o}ggild

arXiv: 1905.00233 · 2019-05-22

## TL;DR

This study explores how edge disorder affects charge induction and quantum capacitance in ballistic graphene devices, revealing inhomogeneous electrostatic profiles and the significant role of quantum effects influenced by magnetic fields.

## Contribution

It provides experimental evidence linking edge disorder to capacitance profiles and quantum effects in graphene, supported by theoretical calculations and magnetoconductance measurements.

## Key findings

- Devices with high edge disorder show homogeneous capacitance profiles.
- Low edge disorder devices exhibit inhomogeneous capacitance influenced by quantum effects.
- Quantum capacitance varies significantly with magnetic field and device edge quality.

## Abstract

We experimentally investigate the charge induction mechanism across gated, narrow, ballistic graphene devices with different degrees of edge disorder. By using magnetoconductance measurements as the probing technique, we demonstrate that devices with large edge disorder exhibit a nearly homogeneous capacitance profile across the device channel, close to the case of an infinitely large graphene sheet. In contrast, devices with lower edge disorder (< 1 nm roughness) are strongly influenced by the fringing electrostatic field at graphene boundaries, in quantitative agreement with theoretical calculations for pristine systems. Specifically, devices with low edge disorder present a large effective capacitance variation across the device channel with a nontrivial, inhomogeneous profile due not only to classical electrostatics but also to quantum mechanical effects. We show that such quantum capacitance contribution, occurring due to the low density of states (DOS) across the device in the presence of an external magnetic field, is considerably altered as a result of the gate electrostatics in the ballistic graphene device. Our conclusions can be extended to any two dimensional (2D) electronic system confined by a hard-wall potential and are important for understanding the electronic structure and device applications of conducting 2D materials.

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Source: https://tomesphere.com/paper/1905.00233