From Narrow-gap Semiconductor to Metallic Altermagnet: Optical Fingerprints of Co-Doped FeSb2

TL;DR

This study demonstrates that cobalt-doped FeSb₂ transitions from a narrow-gap semiconductor to a metallic altermagnet with unique optical fingerprints, providing a new platform for exploring altermagnetism and electron-phonon interactions.

Contribution

It provides experimental and theoretical evidence of metallic altermagnetism in Co-doped FeSb₂, highlighting optical signatures and spin ordering mechanisms.

Findings

Cobalt doping induces a metallic altermagnetic state in FeSb₂.

Infrared optical conductivity reveals low-energy interband transitions related to altermagnetic order.

Enhanced electron-phonon coupling and local inversion symmetry breaking observed upon doping.

Abstract

The realization of bulk metallic altermagnetism has remained elusive despite the growing number of candidate materials. Here, we present evidence that moderate cobalt substitution ($\sim$15%) drives the correlated narrow-gap semiconductor FeSb$_2$ into a metallic altermagnetic state persisting up to room temperature. The infrared optical conductivity reveals low-energy interband transitions near 0.1 eV that emerge upon doping and grow with Co concentration. Density functional theory calculations show that these transitions originate exclusively from altermagnetic spin ordering, with spin split bands ($\sim$0.2 eV) of non-relativistic origin, together with spin-orbit coupling induced band splitting of the order of $\sim$5 meV near the Fermi level. Co substitution further leads to Fano lineshapes and mode mixing in the infrared-active phonons, reflecting enhanced electron-phonon coupling and local inversion symmetry breaking, while leaving the altermagnetic spin symmetry intact. Our results establish carrier-tuned FeSb$_2$ as a platform for exploring metallic $d$-wave altermagnetism and its coupling to lattice degrees of freedom.