Generalized Dicke model and gauge-invariant master equations for two atoms in ultrastrongly-coupled cavity quantum electrodynamics

TL;DR

This paper extends the Dicke model to two dissimilar atoms in ultrastrong coupling, employing gauge-invariant master equations to analyze complex spectral features and resonance phenomena in cavity QED systems.

Contribution

It introduces a gauge-invariant theoretical framework for two dissimilar atoms in ultrastrong coupling, including system-bath interactions, and explores spectral effects of off-resonance and resonance tuning.

Findings

Multiple off-resonance resonances in cavity spectra

Distinct anti-crossing features during atom resonance tuning

Comparison of sensor atom spectrum with quantum regression theorem

Abstract

We study a generalization of the well-known Dicke model, using two dissimilar atoms in the regime of ultrastrongly coupled cavity quantum electrodynamics. Our theory uses gauge invariant master equations, which yields consistent results in either of the standard multipolar and Coulomb gauges, including system-bath interactions for open cavity systems. We first show how a second atom can be treated as a sensor atom to measure the output spectrum from a single atom in the ultrastrong-coupling regime, and compare results with the quantum regression theorem, explaining when they can be different. We then focus on the case where the second atom is also ultrastrongly coupled to the cavity, but with different parameters from those of the first atom, which introduces complex coupling effects and additional resonances and spectral features. In particular, we show multiple resonances in the cavity spectra that are visible off-resonance, which cannot be seen when the second atom is on-resonance with the rest of the system. We also observe clear anti-crossing features particularly pronounced for when the second atom tunes through resonance.