Non-Markovian exceptional points in waveguide quantum electrodynamics

TL;DR

This paper explores the emergence of non-Markovian exceptional points in waveguide quantum electrodynamics, revealing sharp transitions in emission dynamics due to strong non-Markovian effects.

Contribution

It demonstrates the existence of non-Markovian exceptional points in waveguide-QED systems, linking them to observable relaxation dynamics and oscillatory behavior.

Findings

Non-Markovian EPs cause sharp transitions to oscillatory decay.

Real zeros in excited-state amplitude indicate EPs.

Waveguide-QED systems are suitable for studying non-Markovian EP physics.

Abstract

Spontaneous emission of a quantum emitter, such as an excited atom, is a fundamental process in quantum electrodynamics (QED), typically associated with exponential decay to the ground state accompanied by irreversible photon emission. This simple Markovian picture, however, is profoundly modified in the presence of time-delayed feedback, structured continua, or cooperative emission, as occurs when an emitter radiates in front of a mirror, when several emitters radiate collectively, or in the case of a giant atom. In such regimes, strong non-Markovian dynamics arise from photon reabsorption and interference effects, leading to pronounced deviations from exponential decay. Here we demonstrate the emergence of exceptional points (EPs) in these highly non-Markovian waveguide-QED environments, i.e., non-Markovian EPs. These EPs appear directly in the relaxation dynamics as sharp transitions to oscillatory behavior, manifested by the appearance of real zeros in the excited-state amplitude. We analyze in detail the spontaneous emission of giant atoms with two or more coupling points, highlighting the mechanisms leading to non-Markovian EPs, and show that similar phenomena arise in other waveguide-QED settings, such as the collective spontaneous emission of spatially separated point-like emitters. Our results reveal waveguide-QED systems as experimentally accessible platforms for realizing and exploring non-Markovian EP physics.