Related papers: CUT-E as a $1/N$ expansion for multiscale molecular polariton dynamics

CUT-E as a $1/N$ expansion for multiscale molecular polariton dynamics

URL: http://arxiv.org/abs/2410.14175v1
Date: Fri, 18 Oct 2024 04:56:48 GMT
Title: CUT-E as a $1/N$ expansion for multiscale molecular polariton dynamics
Authors: Juan B. Pérez-Sánchez, Arghadip Koner, Sricharan Raghavan-Chitra, Joel Yuen-Zhou,
Abstract summary: Molecular polaritons arise when the collective coupling between an ensemble of $N$ molecules and an optical mode exceeds individual photon and molecular linewidths. We provide a novel derivation of CUT-E based on recently developed bosonization techniques. We lay down its connections with $1/N$ expansions that are ubiquitous in other fields of physics, and present previously unexplored key aspects of this formalism.
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Abstract: Molecular polaritons arise when the collective coupling between an ensemble of $N$ molecules and an optical mode exceeds individual photon and molecular linewidths. The complexity of their description stems from their multiscale nature, where the local dynamics on each molecule can, in principle, be influenced by the collective behavior of the entire ensemble. To address this, we previously introduced a formalism called collective dynamics using truncated equations (CUT-E). CUT-E approaches the problem in two stages. First, it exploits permutational symmetries to obtain a substantial simplification of the problem. However, this is often insufficient for parameter regimes relevant to most experiments. Second, it takes the exact solution of the problem in the $N\to\infty$ limit as a reference and derives systematic $\mathcal{O}(1/N)$ corrections. Here we provide a novel derivation of CUT-E based on recently developed bosonization techniques. We lay down its connections with $1/N$ expansions that are ubiquitous in other fields of physics, and present previously unexplored key aspects of this formalism, including various types of approximations and extensions to high excitation manifolds.

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