Graphene: carbon in two dimensions

TL;DR

Graphene, a two-dimensional form of carbon, exhibits unique electronic properties such as massless electron behavior and quantum Hall effects, opening new avenues in condensed matter physics and electronics.

Contribution

This paper reports the recent synthesis of graphene and explores its novel electronic properties, bridging condensed matter physics and quantum electrodynamics.

Findings

Electrons in graphene behave as massless relativistic particles.

Graphene exhibits an anomalous quantum Hall effect.

It shows an absence of localization, unlike traditional materials.

Abstract

Carbon is one of the most intriguing elements in the Periodic Table. It forms many allotropes, some being known from ancient times (diamond and graphite) and some discovered ten to twenty years ago (fullerenes, nanotubes). Quite interestingly, the two-dimensional form (graphene) has been obtained only very recently, and immediately attracted great deal of attention. Electrons in graphene, obeying linear dispersion relation, behave like massless relativistic particles, which results in a number of very peculiar electronic properties observed in this first two-dimensional material: from an anomalous quantum Hall effect to the absence of localization. It also provides a bridge between condensed matter physics and quantum electrodynamics and opens new perspectives for carbon-based electronics.