Unified Light-Matter Floquet Theory and its Application to Quantum Communication

TL;DR

This paper introduces photon-resolved Floquet theory (PRFT), a unified framework combining Floquet theory with quantum optics, revealing light-matter entanglement and decoherence effects crucial for advancing quantum communication and memory technologies.

Contribution

The paper develops PRFT, integrating Floquet theory with quantum optics via full-counting statistics, enabling analysis of quantum phenomena beyond semiclassical approaches.

Findings

PRFT predicts macroscopic light-matter entanglement.

Decoherence occurs rapidly at optical frequencies, negligible at radio frequencies.

Proposes a quantum communication protocol outperforming existing methods by over two orders of magnitude.

Abstract

Periodically-driven quantum systems can exhibit a plethora of intriguing non-equilibrium phenomena that can be analyzed using Floquet theory. Naturally, Floquet theory is employed to describe the dynamics of atoms interacting with intense laser fields. However, this semiclassical analysis can not account for quantum-optical phenomena that rely on the quantized nature of light. In this paper, we take a significant step to go beyond the semiclassical description of atom-photon coupled systems by unifying Floquet theory with quantum optics using the framework of full-counting statistics. This is achieved by introducing counting fields that keep track of the photonic dynamics. This formalism, which we dub ``photon-resolved Floquet theory" (PRFT), is based on two-point tomographic measurements, instead of the two-point projective measurements used in standard full-counting statistics. Strikingly, the PRFT predicts the generation of macroscopic light-matter entanglement when atoms interact with multimode electromagnetic fields, thereby leading to complete decoherence of the atomic subsystem in the basis of the Floquet states. This decoherence occurs rapidly in the optical frequency regime, but is negligible in the radio frequency regime. Our results thus pave the way for the design of efficient quantum memories and quantum operations. Finally, employing the PRFT, we propose a quantum communication protocol that can significantly outperform the state-of-art few-photon protocols by two orders of magnitude or better. The PRFT potentially leads to insights in various Floquet settings including spectroscopy, thermodynamics, quantum metrology, and quantum simulations.