Abstract
Exceptional points (EPs), at which both eigenvalues and eigenvectors coalesce, are ubiquitous and unique features of non-Hermitian systems. Second-order EPs are by far the most studied due to their abundance, requiring only the tuning of two real parameters, which is less than the three parameters needed to generically find ordinary Hermitian eigenvalue degeneracies. Higher-order EPs generically require more fine-tuning, and are thus assumed to play a much less prominent role. Here, however, we illuminate how physically relevant symmetries make higher-order EPs dramatically more abundant and conceptually richer. More saliently, third-order EPs generically require only two real tuning parameters in the presence of either a parity-time (PT) symmetry or a generalized chiral symmetry. Remarkably, we find that these different symmetries yield topologically distinct types of EPs. We illustrate our findings in simple models, and show how third-order EPs with a generic ∼k^{1/3} dispersion are protected by PT symmetry, while third-order EPs with a ∼k^{1/2} dispersion are protected by the chiral symmetry emerging in non-Hermitian Lieb lattice models. More generally, we identify stable, weak, and fragile aspects of symmetry-protected higher-order EPs, and tease out their concomitant phenomenology.
Highlights
Introduction.—With the advent of non-Hermitian (NH) topological phases [1], exceptional points (EPs) have become an interdisciplinary frontier of research, with applications ranging from classical metamaterials to quantum condensed matter systems [1,2]
We illustrate our findings in simple models, and show how third-order Exceptional points (EPs) with a generic ∼k1=3 dispersion are protected by PT symmetry, while thirdorder EPs with a ∼k1=2 dispersion are protected by the chiral symmetry emerging in non-Hermitian Lieb lattice models
For the aforementioned case of n 1⁄4 2, generic NH symmetries have been found to reduce the codimension of EPs from two to one, enabling symmetry-protected second-order EPs even in 1D systems [11,12,13,14,15,16]
Summary
Introduction.—With the advent of non-Hermitian (NH) topological phases [1], exceptional points (EPs) have become an interdisciplinary frontier of research, with applications ranging from classical metamaterials to quantum condensed matter systems [1,2]. Second-order EPs are by far the most studied due to their abundance, requiring only the tuning of two real parameters, which is less than the three parameters needed to generically find ordinary Hermitian eigenvalue degeneracies. We illuminate how physically relevant symmetries make higher-order EPs dramatically more abundant and conceptually richer.
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