D-Wave Phonon Angular Momentum Texture in Altermagnets by Magnon-Phonon-Hybridization

TL;DR

This paper theoretically explores how magnon-phonon hybridization in altermagnets leads to quasiparticles with finite phonon angular momentum, revealing potential for phononic spin-splitter effects driven by temperature gradients.

Contribution

It introduces the concept of phonon angular momentum textures in altermagnets caused by magnon-phonon hybridization via Dzyaloshinskii-Moriya interaction, a novel theoretical insight.

Findings

Hybrid quasiparticles with phonon angular momentum emerge in altermagnets.

Phonon angular momentum texture follows the d-wave magnon spin texture.

Potential for phononic spin-splitter effects analogous to electronic responses.

Abstract

In altermagnets, the magnon bands are anisotropically spin-split in reciprocal space without relativistic or dipolar spin-spin interactions. In this work, we theoretically study magnons and phonons coupled by spin-lattice interaction in a two-dimensional square-lattice d-wave altermagnet. We show that phonon-chirality-selective magnon-phonon hybridization can be caused by interfacial Dzyaloshinskii-Moriya interaction leading to the emergence of hybrid quasiparticles that possess finite phonon angular momentum. These hybrid quasiparticles are called magnon polarons and consist of spin-polarized magnons and chiral phonons. Their phonon angular momentum texture follows the d-wave character of the magnon spin texture opening up the possibility of phononic counterparts to the electronic response effects in altermagnets, such as a phonon angular momentum splitter effect, i.e., the generation of a transverse phonon angular momentum current induced by a temperature gradient -- the bosonic analogue of the spin-splitter effect.