Litcius/Paper detail

Photonic quadrupole topological insulator using orbital-induced synthetic flux

Julian Schulz, Jiho Noh, Wladimir A. Benalcazar, Gaurav Bahl, Georg von Freymann

2022Nature Communications67 citationsDOIOpen Access PDF

Abstract

The rich physical properties of multiatomic crystals are determined, to a significant extent, by the underlying geometry and connectivity of atomic orbitals. The mixing of orbitals with distinct parity representations, such as s and p orbitals, has been shown to be useful for generating systems that require alternating phase patterns, as with the sign of couplings within a lattice. Here we show that by breaking the symmetries of such mixed-orbital lattices, it is possible to generate synthetic magnetic flux threading the lattice. We use this insight to experimentally demonstrate quadrupole topological insulators in two-dimensional photonic lattices, leveraging both s and p orbital-type modes. We confirm the nontrivial quadrupole topology by observing the presence of protected zero-dimensional states, which are spatially confined to the corners, and by confirming that these states sit at mid-gap. Our approach is also applicable to a broader range of time-reversal-invariant synthetic materials that do not allow for tailored connectivity, and in which synthetic fluxes are essential.

Topics & Concepts

PhysicsMultipole expansionAtomic orbitalTopology (electrical circuits)Topological insulatorQuadrupoleLattice (music)Condensed matter physicsQuantum mechanicsElectronMathematicsAcousticsCombinatoricsTopological Materials and PhenomenaStrong Light-Matter InteractionsNonlinear Photonic Systems