Ultrastrong light-matter coupling in near-field coupled split-ring resonators revealed by photocurrent spectroscopy

TL;DR

This paper demonstrates ultrastrong light-matter coupling in near-field coupled split-ring resonators using photocurrent spectroscopy, revealing hybridization with bright, dark, and topological modes, and exploring multi-mode interactions.

Contribution

It introduces the first experimental observation of ultrastrong coupling in near-field coupled SRRs and explores complex mode hybridization and topological effects.

Findings

Ultrastrong coupling observed in near-field SRR configurations.

Hybridization with bright, dark, and topological edge modes.

Engineered near-field interactions enable multi-mode ultrastrong coupling.

Abstract

Landau polaritons arising from the coupling between cyclotron resonance and terahertz split-ring resonators (SRRs) have served as a central platform for exploring ultrastrong light-matter interaction for more than a decade. Over this period, a wide variety of SRR architectures, differing in size, geometry, and even material composition, have been investigated. However, the regime of near-field coupled SRRs has remained largely unexplored. Here, we demonstrate ultrastrong coupling using photocurrent spectroscopy in two prototypical near-field configurations: a SRR dimer and a topological SRR chain. The measurements reveal hybridization not only with bright resonant modes but also with optically dark modes and topological edge modes, highlighting the exceptional sensitivity of the photocurrent spectroscopy. Moreover, the engineered near-field interactions allow the study of multi-mode ultrastrong coupling and the interplay between topological band structure and cavity quantum electrodynamics.