Photonic quadrupole topological insulator using orbital-induced synthetic flux

TL;DR

This paper demonstrates a novel method to realize a quadrupole topological insulator in photonic systems by inducing synthetic magnetic flux through orbital symmetry breaking, enabling higher-order topological phases without complex connectivity.

Contribution

The authors introduce a new approach to generate synthetic flux in orbital lattices, enabling the experimental realization of a quadrupole topological insulator in photonics.

Findings

Confirmed quadrupole topology via protected corner states

Demonstrated synthetic flux generation through orbital symmetry breaking

Applicable to broader time-reversal-invariant synthetic materials

Abstract

The rich physical properties of multiatomic molecules and crystalline structures are determined, to a significant extent, by the underlying geometry and connectivity of atomic orbitals. This orbital degree of freedom has also been used effectively to introduce structural diversity in a few synthetic materials including polariton lattices nonlinear photonic lattices and ultracold atoms in optical lattices. In particular, the mixing of orbitals with distinct parity representations, such as $s$ and $p$ orbitals, has been shown to be especially useful for generating systems that require alternating phase patterns, as with the sign of couplings within a lattice. Here we show that by further breaking the symmetries of such mixed-orbital lattices, it is possible to generate synthetic magnetic flux threading the lattice. This capability allows the generation of multipole higher-order topological phases in synthetic bosonic platforms, in which $\pi$ flux threading each plaquette of the lattice is required, and which to date have only been implemented using tailored connectivity patterns. We use this insight to experimentally demonstrate a quadrupole photonic topological insulator in a two-dimensional lattice of waveguides that leverage modes with both $s$ and $p$ orbital-type representations. We confirm the nontrivial quadrupole topology of the system by observing the presence of protected zero-dimensional states, which are spatially confined to the corners, and by confirming that these states sit at the band gap. Our approach is also applicable to a broader range of time-reversal-invariant synthetic materials that do not allow for tailored connectivity, e.g. with nanoscale geometries, and in which synthetic fluxes are essential.