English

Hybrid confinement techniques for polariton simulators

Optics 2025-12-04 v2 Mesoscale and Nanoscale Physics Applied Physics

Abstract

Exciton-polariton III-V semiconductor microcavities provide a robust platform for emulating complex Hamiltonians, enabling topological photonics and quantum simulation for advanced photonic functionalities. Here, we introduce two novel fabrication techniques - etch-and-oversputter and deposit-and-oversputter - that overcome limitations of traditional photonic confinement. Both use structured, locally elongated semiconductor cavities to create deep, highly controllable potentials, while leveraging high-quality GaAs-based materials, which achieve excellent Q-factors. A sputtered all-dielectric top mirror introduces an innovative hybrid approach, simplifying fabrication while maintaining quality compared to deep ion etching. Utilizing a Kagome lattice as a benchmark, we show high-quality optical band structures previously inaccessible with deep etching. Furthermore, we study a two-dimensional breathing Kagome lattice and demonstrate polariton lasing from a zero-dimensional corner mode, confirming precise control over couplings and tight polariton localization. These methods enable fabrication of intricate lattices, including higher-order topological insulators, or on-chip quantum regimes utilizing the polariton blockade mechanism due to tight photonic confinement.

Keywords

Cite

@article{arxiv.2503.02355,
  title  = {Hybrid confinement techniques for polariton simulators},
  author = {Johannes Düreth and Philipp Gagel and David Laibacher and Oleg A. Egorov and Simon Widmann and Simon Betzold and Monika Emmerling and Siddhartha Dam and Alexia Landry and Christian G. Mayer and Martin Kamp and Aniela Woyciechowska and Barbara Piętka and Ulf Peschel and Sven Höfling and Sebastian Klembt},
  journal= {arXiv preprint arXiv:2503.02355},
  year   = {2025}
}
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