Topologically protected subradiant cavity polaritons through linewidth narrowing enabled by dissipationless edge states

TL;DR

This paper proposes a topological design for cavity polaritons that significantly enhances their lifetime and coherence by leveraging dissipationless edge states, enabling robust quantum states for advanced quantum technologies.

Contribution

It introduces a topological atom array-based resonator that creates subradiant cavity polaritons with linewidth narrowing and robustness against disorder, surpassing previous approaches.

Findings

Lifetime of cavity polaritons increased over tenfold.

Subradiant polaritons exhibit linewidths below single emitter decay.

Topological protection ensures robustness against moderate disorder.

Abstract

Cavity polaritons derived from the strong light-matter interaction at the quantum level provide a basis for efficient manipulation of quantum states via cavity field. Polaritons with narrow linewidth and long lifetime are appealing in applications such as quantum sensing and storage. Here, we propose a prototypical arrangement to implement a whispering-gallery-mode resonator with topological mirror moulded by one-dimensional atom array, which allows to boost the lifetime of cavity polaritons over an order of magnitude. This considerable enhancement attributes to the coupling of polaritonic states to dissipationless edge states protected by the topological bandgap of atom array that suppresses the leakage of cavity modes. When exceeding the width of Rabi splitting, topological bandgap can further reduce the dissipation from polaritonic states to bulk states of atom array, giving arise to subradiant cavity polaritons with extremely sharp linewidth. The resultant Rabi oscillation decays with a rate even below the free-space decay of a single quantum emitter. Inheriting from the topologically protected properties of edge states, the subradiance of cavity polaritons can be preserved in the disordered atom mirror with moderate perturbations involving the atomic frequency, interaction strengths and location. Our work opens up a new paradigm of topology-engineered quantum states with robust quantum coherence for future applications in quantum computing and network.