Altermagnetic lifting of Kramers spin degeneracy

TL;DR

This paper confirms that altermagnetic phases can lift Kramers spin degeneracy without net magnetization or inversion symmetry breaking, revealing new magnetic phenomena with broad implications across various materials.

Contribution

It provides experimental and theoretical evidence for altermagnetic lifting of Kramers degeneracy in centrosymmetric MnTe, a novel mechanism distinct from traditional magnetic or spin-orbit effects.

Findings

Confirmed altermagnetic lifting of Kramers degeneracy via photoemission and ab initio calculations.

Identified two mechanisms of degeneracy lifting in MnTe's altermagnetic phase.

Demonstrated potential for broad applications in diverse materials.

Abstract

Lifted Kramers spin-degeneracy has been among the central topics of condensed-matter physics since the dawn of the band theory of solids. It underpins established practical applications as well as current frontier research, ranging from magnetic-memory technology to topological quantum matter. Traditionally, lifted Kramers spin-degeneracy has been considered to originate from two possible internal symmetry-breaking mechanisms. The first one refers to time-reversal symmetry breaking by magnetization of ferromagnets, and tends to be strong due to the non-relativistic exchange-coupling origin. The second mechanism applies to crystals with broken inversion symmetry, and tends to be comparatively weaker as it originates from the relativistic spin-orbit coupling. A recent theory work based on spin-symmetry classification has identified an unconventional magnetic phase, dubbed altermagnetic, that allows for lifting the Kramers spin degeneracy without net magnetization and inversion-symmetry breaking. Here we provide the confirmation using photoemission spectroscopy and ab initio calculations. We identify two distinct unconventional mechanisms of lifted Kramers spin degeneracy generated by the altermagnetic phase of centrosymmetric MnTe with vanishing net magnetization. Our observation of the altermagnetic lifting of the Kramers spin degeneracy can have broad consequences in magnetism. It motivates exploration and exploitation of the unconventional nature of this magnetic phase in an extended family of materials, ranging from insulators and semiconductors to metals and superconductors, that have been either identified recently or perceived for many decades as conventional antiferromagnets.