Related papers: Super-dephasing in Collective Atom-Atom Interactions Mediated by Near-Field Electromagnetic Fluctuations

Super-dephasing in Collective Atom-Atom Interactions Mediated by Near-Field Electromagnetic Fluctuations

URL: http://arxiv.org/abs/2402.18816v2
Date: Tue, 17 Sep 2024 06:44:51 GMT
Title: Super-dephasing in Collective Atom-Atom Interactions Mediated by Near-Field Electromagnetic Fluctuations
Authors: Wenbo Sun, Adrian E. Rubio López, Zubin Jacob,
Abstract summary: We introduce the nano-EM super-dephasing phenomenon arising in the photonic environments near materials. Long-range correlations in off-resonant, low-frequency evanescent EM fluctuations lead to collectively accelerated (super-) or suppressed (sub-) dephasing in many-body entangled states.
Score: 8.612606763875648
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Pure dephasing and spontaneous emission are two non-unitary processes of atoms or spins interacting with fluctuating electromagnetic (EM) modes. The dissipative collective emission processes (e.g., superradiance) originate from interactions with EM modes in resonance with atoms and have received considerable attention. Meanwhile, the analogous non-dissipative collective dephasing phenomena mediated by EM environments remain poorly understood. Here, we introduce the nano-EM super-dephasing phenomenon arising in the photonic environments near materials. We show that collective dephasing in this nano-EM environment is enhanced by over 10 orders of magnitude compared to free space or cavities. This giant enhancement originates from long-range correlations in off-resonant, low-frequency evanescent EM fluctuations, which lead to collectively accelerated (super-) or suppressed (sub-) dephasing in many-body entangled states. We further unravel that nano-EM collective dephasing exhibits universal interaction ranges near materials with different anisotropy that can be reciprocal or non-reciprocal. This nano-EM interaction range, which is not present in free-space and cavities, leads to unique scaling laws of super-dephasing in GHZ states different from the conventional $N^2$ scaling of superradiance. Finally, we discuss how to experimentally isolate and control super-dephasing to open interesting frontiers for scalable quantum systems.

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