Atom-Field-Medium Interactions I: Graded Influence Actions for $N$ Harmonic Atoms in a Dielectric-Altered Quantum Field

TL;DR

This paper develops a graded influence action formalism to model multi-layered open quantum systems, specifically analyzing $N$ harmonic atoms interacting with a dielectric-altered quantum field, revealing non-Markovian effects and medium modifications.

Contribution

It introduces a novel graded influence action approach for layered quantum systems and applies it to atom-field-medium interactions, capturing complex back-action effects.

Findings

Derived stochastic equations for atomic internal degrees of freedom.

Identified non-Markovian spatial correlations in dielectric.

Showed dielectric medium modifies quantum field via frequency-dependent permittivity.

Abstract

This series of papers has two broader aims: 1) Construct a theory for multi-partite open quantum systems comprising several layers of structure with self-consistent back-actions. Develop the graded influence action formalism \cite{BehHu10,BH11} to account for the influences of successive sub-layers on the dynamics of the variables of interest. 2) Apply these methods to the study of atom-field-medium interactions and highlight their merits over conventional methods. We consider a system of $N$ harmonic oscillators, modeling the internal degrees of freedom (idf) of $N$ neutral atoms (A), interacting with a quantum field (F), scalar here, for simplicity, altered by the presence of a dielectric medium (M). In this paper we use the coarse-grained and stochastic effective actions in the influence functional formalism to derive the stochastic equations for the reduced density matrices of the dynamical variables in the successive layers of structure. The word `graded' refers to the specific ordering of the coarse-graining procedures. Three layers of coarse-graining are performed, firstly, integrating over the common bath of the dielectric oscillators results not only in the appearance of necessary dissipative properties of the dielectric but also essential nuanced features such as nonMarkovian spatial correlations in the dielectric. Secondly, integrating over the medium variables as a whole results in a dielectric-modified quantum field, the influence of the medium on the quantum field manifesting through a frequency-dependent permittivity function. Finally, integrating over this dielectric-altered quantum field which interacts with the idfs of the atoms yields an influence action. From it we obtain the stochastic equation of motion which describes the nonequilibrium stochastic dynamics of the idf of the atoms interacting with a dielectric medium-modified quantum field.