Observation of localization of light in photonic quasicrystals of diverse symmetries

TL;DR

This study experimentally demonstrates linear light localization in two-dimensional photonic quasicrystals with various symmetries, revealing the conditions for localization and its dependence on symmetry order, thus advancing understanding of wave behavior in aperiodic structures.

Contribution

First direct experimental observation of linear light localization in purely linear photonic quasicrystals with diverse symmetries, clarifying the conditions for localization.

Findings

Light localization occurs above a critical potential depth.

Critical depth decreases with higher rotational symmetry.

Localization is observed both at the center and off-center regions.

Abstract

Quasicrystals are ubiquitous in nature. Beyond crystalline solids, they can be created as optically induced or technologically fabricated structures in photonic and phononic systems, as potentials for cold atoms and Bose-Einstein condensates (BECs). On a parwith the unusual structural properties of quasicrystals, nowadays the problem of wave propagation in such two-dimensional structures attracts considerable attention, already in earlier studies it was predicted that the lowest electronic states in five-fold quasicrystals are localized. Later on localization of BECs in an eight-fold rotational symmetric quasicrystal optical lattices was observed. Direct observation of localization in purely linear photonic quasicrystals, therefore, remains elusive. Here, using sets of interfering plane waves, we create photonic two-dimensional quasicrystals with different rotational symmetries, not allowed in periodic crystallographic structures. We demonstrate experimentally that linear localization of light does occur even in clean linear quasicrystals for probe beams propagating both in the center and off-center regions of the quasicrystals. We found that light localization occurs above a critical depth of optically induced potential and that this critical depth rapidly decreases with the increase of the order of the discrete rotational symmetry of the quasicrystal. Our results clarify a long-standing problem of wave localization in linear quasicrystals and elucidate the conditions under which this phenomenon occurs. These findings pave the way for achieving wave localization in a wide variety of aperiodic systems obeying discrete symmetries, with possible applications in photonics, atomic physics, acoustics, and condensed matter.