Direct experimental evidence of pi magnetism of a single atomic vacancy in graphene

TL;DR

This study provides direct experimental evidence of pi magnetism in graphene with atomic vacancies, revealing spin-polarized states and Zeeman splitting using scanning tunnelling microscopy.

Contribution

It is the first to directly observe pi magnetism at atomic vacancies in graphene through experimental measurements.

Findings

Localized states split into two spin-polarized DOS peaks

Energy separation of peaks increases with magnetic field

Giant effective g-factor (~40) observed near vacancies

Abstract

The pristine graphene is strongly diamagnetic. However, graphene with single carbon atom defects could exhibit paramagnetism with local magnetic moments ~ 1.5 per vacancy1-6. Theoretically, both the electrons and electrons of graphene contribute to the magnetic moment of the defects, and the pi magnetism is characterizing of two spin-split DOS (density-of-states) peaks close to the Dirac point1,6. Since its prediction, many experiments attempt to study this pi magnetism in graphene, whereas, only a notable resonance peak has been observed around the atomic defects6-9, leaving the pi magnetism experimentally so elusive. Here, we report direct experimental evidence of the pi magnetism by using scanning tunnelling microscope. We demonstrate that the localized state of the atomic defects is split into two DOS peaks with energy separations of several tens meV and the two spin-polarized states degenerate into a profound peak at positions with distance of ~ 1 nm away from the monovacancy. Strong magnetic fields further increase the energy separations of the two spin-polarized peaks and lead to a Zeeman-like splitting. The effective g-factors geff around the atomic defect is measured to be about 40. Such a giant enhancement of the g-factor is attributed to the strong spin polarization of electron density and large electron-electron interactions near the atomic vacancy.