Related papers: Exact solution for the collective non-Markovian decay of two fully excited quantum emitters

Exact solution for the collective non-Markovian decay of two fully excited quantum emitters

URL: http://arxiv.org/abs/2403.13871v2
Date: Tue, 14 May 2024 07:51:13 GMT
Title: Exact solution for the collective non-Markovian decay of two fully excited quantum emitters
Authors: Alfonso Lanuza, Dominik Schneble,
Abstract summary: We analyze a collective non-Markovian decay in a minimal system of two excited emitters coupled to a one-dimensional waveguide. Our methods shed light on the complexity of collective light-matter interactions and open up a pathway for understanding multiparticle open quantum systems.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Waveguide quantum electrodynamics constitutes a modern paradigm for the interaction of light and matter, in which strong coupling, bath structure, and propagation delays can break the radiative conditions that quantum emitters typically encounter in free space. These characteristics intertwine the excitations of quantum emitters and guided radiation modes to form complex multiphoton dynamics. So far, combining the collective decay of the emitters with the non-Markovian effects induced by the modes has escaped a full solution and the detailed physics behind these systems remains unknown. Here we analyze such a collective non-Markovian decay in a minimal system of two excited emitters coupled to a one-dimensional single-band waveguide. We develop an exact solution for this system in terms of elementary functions that unveils hidden symmetries and predicts new forms of spontaneous decay. The collective non-Markovian dynamics, which are strongly dependent on the vacuum coupling and the detuning from the center of the band, show exotic features that can be characterized with a simple and readily available criterion. Our analytic methods shed light on the complexity of collective light-matter interactions and open up a pathway for understanding multiparticle open quantum systems.

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