Abelian Spectral Topology of Multifold Exceptional Points

TL;DR

This paper provides a mathematically rigorous classification of multifold exceptional points in non-Hermitian systems, revealing their topological properties, including new $bZ_2$-protected Fermi arcs, and extends existing theories with broader symmetry considerations.

Contribution

It introduces a generalized topological classification of EP$n$s using similarity relations and vector bundle theory, expanding understanding of their mathematical and physical properties.

Findings

Topological classification of EP$n$s using similarity relations.

Prediction of $bZ_2$-protected Fermi arcs due to non-local symmetries.

Connection of topological invariants to vector bundle theory and tenfold classification.

Abstract

The advent of non-Hermitian physics has enriched the plethora of topological phases to include phenomena without Hermitian counterparts. Despite being among the most well-studied uniquely non-Hermitian features, the topological properties of multifold exceptional points, $n$-fold spectral degeneracies (EP$n$s) at which also the corresponding eigenvectors coalesce, were only recently revealed in terms of topological resultant winding numbers and concomitant Abelian doubling theorems. Nevertheless, a more mathematically fundamental description of EP$n$s and their topological nature has remained an open question. To fill this void, in this article, we revisit the topological classification of EP$n$s in generic systems and systems with local symmetries, generalize it in terms of more mathematically tractable (local) similarity relations, and extend it to include all such similarities as well as non-local symmetries. Through the resultant vector, whose components are given in terms of the resultants between the corresponding characteristic polynomial and its derivatives, the topological nature of the resultant winding number is understood in several ways: in terms of i) the tenfold classification of (Hermitian) topological matter, ii) the framework of Mayer--Vietoris sequence, and iii) the classification of vector bundles. The classification scheme further predicts the existence of topological bulk Fermi arcs protected by a $\mathbb{Z}_2$-invariant, induced by non-local symmetries, dubbed $\mathbb{Z}_2$-protected Fermi arcs. Our work reveals the mathematical foundations on which the topological nature of EP$n$s resides, enriches the theoretical understanding of non-Hermitian spectral features, and will therefore find great use in modern experiments within both classical and quantum physics.