Non-Hermitian Morphing of Topological Modes

TL;DR

This paper demonstrates experimentally how non-Hermitian effects can delocalize topological modes in mechanical lattices, revealing new behaviors and potential applications in topological systems.

Contribution

It shows that non-Hermitian skin effects can cause topological modes to become extended, challenging traditional localization notions and enabling mode deformation.

Findings

Extended topological modes observed in 1D and 2D lattices

Topological modes remain robust despite delocalization

Non-Hermitian engineering enables shape control of modes

Abstract

Topological modes (TMs) are usually localized at defects or boundaries of a much larger topological lattice. Recent studies of non-Hermitian band theories unveiled the non-Hermitian skin effect (NHSE), by which the bulk states collapse to the boundary as skin modes. Here, we experimentally demonstrate that the NHSE can conversely affect wavefunctions of TMs by delocalizing them from the boundary. At a critical non-Hermitian parameter, the in-gap TMs even become completely extended in the entire bulk lattice, forming an extended mode outside of a continuum. These extended modes are still protected by bulk-band topology, making them robust against local disorders. The delocalization effect is experimentally realized in active mechanical lattices in both one-dimensional (1D) and two-dimensional (2D) topological lattices, as well as in a higher-order topological lattice. Furthermore, by the judicious engineering of the non-Hermiticity distribution, the TMs can deform into a diversity of shapes. Our findings not only broaden and deepen the current understanding of the TMs and the NHSE but also open new grounds for topological applications.