Hybrid confinement techniques for polariton simulators

Abstract: Exciton-polaritons in III-V semiconductor microcavities offer a robust platform for emulating complex Hamiltonians, enabling advancements in photonic applications and quantum simulation. Here, two novel fabrication techniques designed to overcome the limitations of traditional photonic confinement methods are introduced. The two distinct approaches - etch-and-oversputter (EnS) and deposit-and-oversputter (DnS) - are both based on a structured, locally elongated semiconductor cavity, leading to a deep and highly controllable spatially dependent potential. By utilizing an all-dielectric sputtered top mirror, sample iteration time, workflow complexity and expense is reduced while increasing the overall yield compared to methods such as deep ion etching. Employing a Kagome lattice and its flatband and Dirac-cone dispersions as a benchmark, high quality optical band structures are achieved, which so far have not been realized using a deep etching approach. To highlight the precise control over the lattice couplings, the eigenmodes in a two-dimensional breathing Kagome lattice are studied and polariton lasing from a zerodimensional corner mode is observed. This confirms the effectiveness of the methods presented in this paper for generating well-controlled, deep and homogeneous trapping potentials. These pave the way for fabricating intricate lattices, such as higher-order topological insulators, or on-chip quantum emitters utilizing the polariton blockade mechanism.