Collective dynamics Using Truncated Equations (CUT-E): simulating the
collective strong coupling regime with few-molecule models
- URL: http://arxiv.org/abs/2209.04955v2
- Date: Tue, 11 Oct 2022 20:58:56 GMT
- Title: Collective dynamics Using Truncated Equations (CUT-E): simulating the
collective strong coupling regime with few-molecule models
- Authors: Juan B. P\'erez-S\'anchez, Arghadip Koner, Nathaniel P. Stern, Joel
Yuen-Zhou
- Abstract summary: We exploit permutational symmetries to drastically reduce the computational cost of textitab-initio quantum dynamics simulations for large $N$.
We show that addition of $k$ extra effective molecules is enough to account for phenomena whose rates scale as $mathcalO(N-k)$.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The study of molecular polaritons beyond simple quantum emitter ensemble
models (e.g., Tavis-Cummings) is challenging due to the large dimensionality of
these systems (the number of molecular emitters is $N\approx 10^{6}-10^{10}$)
and the complex interplay of molecular electronic and nuclear degrees of
freedom. This complexity constraints existing models to either coarse-grain the
rich physics and chemistry of the molecular degrees of freedom or artificially
limit the description to a small number of molecules. In this work, we exploit
permutational symmetries to drastically reduce the computational cost of
\textit{ab-initio} quantum dynamics simulations for large $N$. Furthermore, we
discover an emergent hierarchy of timescales present in these systems, that
justifies the use of an \textit{effective} single molecule to approximately
capture the dynamics of the entire ensemble, an approximation that becomes
exact as $N\rightarrow \infty$. We also systematically derive finite $N$
corrections to the dynamics, and show that addition of $k$ extra effective
molecules is enough to account for phenomena whose rates scale as
$\mathcal{O}(N^{-k})$. Based on this result, we discuss how to seamlessly
modify existing single-molecule strong coupling models to describe the dynamics
of the corresponding ensemble, as well as the crucial differences in phenomena
predicted by each model. We call this approach Collective dynamics Using
Truncated Equations (CUT-E), benchmark it against well-known results of
polariton relaxation rates, and apply it to describe a universal
cavity-assisted energy funneling mechanism between different molecular species.
Beyond being a computationally efficient tool, this formalism provides an
intuitive picture for understanding the role of bright and dark states in
chemical reactivity, necessary to generate robust strategies for polariton
chemistry.
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