Broadband nonlinear optical microresonator array for topological second harmonic generation

Topological photonics enables robust light manipulation with third-order optical nonlinearity, yet integrating second-order optical nonlinearity into a topological system faces fundamental challenges: frequency-dependent topological bandgaps impede simultaneous edge states for pump and second harmonic photons at an octave. Here we present a broadband topological nonlinear photonic system via dual frequency topological bandgap engineering in a 2D nonlinear microresonator array. By designing a square lattice with synthetic magnetic fluxes, we achieve topological phase matching preserving unidirectional edge states for both frequencies while enabling efficient second-harmonic generation. The system exhibits flux-programmable SH chirality, where SH photons reverse propagation direction via Chern number transitions (e.g. C = -1 to +1) without sacrificing robustness. Moreover, we show that the design theoretically yields over 100 times higher SHG efficiency than single resonators at high powers via topology-enhanced coherent buildup. Our topological SHG works in a parameter regime that can be readily accessed by using existing low-loss integrated photon platforms like thin film lithium niobite.