Role of electronic excitation on the anomalous magnetism of elemental Copper

TL;DR

This study reveals that the anomalous low-temperature magnetic susceptibility in elemental copper is due to thermally excited electronic holes in the 3d band, showing intrinsic electronic excitation effects can cause magnetic anomalies.

Contribution

It demonstrates that the Curie tail in copper's magnetic susceptibility is intrinsic and caused by electronic excitations, not impurities or defects.

Findings

Magnetic anomaly linked to holes in Cu 3d band

Electronic excitations induce intrinsic magnetic states

Curie tail can be an intrinsic property of simple metals

Abstract

Magnetic susceptibility of elemental copper (Cu) shows an anomalous rise at low temperatures superimposed on the expected atypical diamagnetic response. Such temperature dependent susceptibility, which is also known as the Curie tail, can not be explained on the basis of Larmor diamagnetic and Pauli paramagnetic contributions expected in Cu. Using valence band resonant photoemission spectroscopy results and density functional theory calculations, we show the magnetic anomaly appears due to presence of holes in Cu 3d band, which originates from thermally excited electronic configuration. Our study therefore highlights that the Curie tail, which is generally overlooked presuming it either due to paramagnetic impurities or defects, can in fact be intrinsic to a material, and even simple systems like elemental Cu is susceptible to electronic excitations giving rise to anomalous magnetic state.