Non-Hermitian Higher-Order Dirac Semimetals

TL;DR

This paper explores 3D non-Hermitian higher-order Dirac semimetals with real spectra, revealing novel topological phases, exceptional Fermi-rings, and higher-order hinge states, advancing understanding of non-Hermitian topological materials.

Contribution

It introduces the concept of hybrid-PT topological phases in non-Hermitian Dirac semimetals and characterizes their higher-order topology using a biorthogonal quadrupole moment.

Findings

Real bulk spectra with exceptional Fermi-rings connecting Dirac nodes

Real hinge-arcs linking surface exceptional Fermi-rings

Discovery of novel phases with hinge arcs and skin-topological modes

Abstract

In this article we study 3D non-Hermitian higher-order Dirac semimetals (NHHODSMs). Our focus is on $C_4$-symmetric non-Hermitian systems where we investigate inversion ($\mathcal{I}$) or time-reversal ($\mathcal{T}$) symmetric models of NHHODSMs having real bulk spectra. We show that they exhibit the striking property that the bulk and surfaces are anti-PT and PT symmetric, respectively, and so belong to two different topological classes realizing a novel non-Hermitian topological phase which we call a \emph{hybrid-PT topological phases}. Interestingly, while the bulk spectrum is still fully real, we find that exceptional Fermi-rings (EFRs) appear connecting the two Dirac nodes on the surface. This provides a route to probe and utilize both the bulk Dirac physics and exceptional rings/points on equal footing. Moreover, particularly for $\mathcal{T}$-NHHODSMs, we also find real hinge-arcs connecting the surface EFRs. We show that this higher-order topology can be characterized using a biorthogonal real-space formula of the quadrupole moment. Furthermore, by applying Hermitian $C_4$-symmetric perturbations, we discover various novel phases, particularly: (i) an intrinsic $\mathcal{I}$-NHHODSM having hinge arcs and gapped surfaces, and (ii) a novel $\mathcal{T}$-symmetric skin-topological HODSM which possesses both topological and skin hinge modes. The interplay between non-Hermition and higher-order topology in this work paves the way toward uncovering rich phenomena and hybrid functionality that can be readily realized in experiment.