Topological continuum charges of acoustic phonons in 2D

TL;DR

This paper investigates the topological properties of acoustic phonons in 2D materials, revealing new non-trivial nodal charges at the Brillouin zone center, with implications for phonon behavior in graphene and beyond.

Contribution

It introduces a novel topological framework considering physical constraints to identify non-trivial nodal charges in 2D phonon spectra, especially in graphene.

Findings

Discovery of non-trivial nodal charges at the $a5$-point in 2D acoustic phonons.

Application of the framework to graphene shows these charges are present in real materials.

The analysis predicts how substrate interactions modify phonon dispersion.

Abstract

We analyze the band topology of acoustic phonons in 2D materials by considering the interplay of spatial and internal symmetries with additional constraints that arise from the physical context. These supplemental constraints trace back to the Nambu-Goldstone theorem and the requirements of structural stability. We show that this interplay can give rise to previously unaddressed non-trivial nodal charges that are associated with the crossing of the acoustic phonon branches at the center ($\Gamma$-point) of the phononic Brillouin zone. We moreover apply our perspective to the concrete context of graphene, where we demonstrate that the phonon spectrum harbors these kinds of non-trivial nodal charges. Apart from its fundamental appeal, this analysis is physically consequential and dictates how the phonon dispersion is affected when graphene is grown on a substrate. Given the generality of our framework, we anticipate that our strategy that thrives on combining physical context with insights from topology should be widely applicable in characterizing systems beyond electronic band theory.