Closed time path approach to the Casimir energy in real media

TL;DR

This paper uses the closed time path formalism to analyze the non-equilibrium quantum dynamics of the energy-momentum tensor of a scalar field interacting with real materials, revealing transient behaviors and long-term contributions of field and material effects.

Contribution

It introduces a generalized framework for studying quantum fluctuations in non-equilibrium scenarios with real materials, including both bilinear and current-type couplings, and derives explicit dynamical evolution expressions.

Findings

Transient contributions from both material and field identified.

Long-time steady state contributions depend on material dissipation.

In 1+1 dimensions, both contributions are essential for proper quantization.

Abstract

The closed time path formalism is applied, in the framework of open quantum systems, to study the time evolution of the expectation value of the energy-momentum tensor of a scalar field in the presence of real materials. We analyze quantum fluctuations in a fully non-equilibrium scenario, when the scalar field is interacting with the polarization degrees of freedom of matter, described as quantum Brownian particles. A generalized analysis was done for two types of couplings between the field and the material. On the one hand, we considered a bilinear coupling, and on the other hand, a (more realistic) current-type coupling as in the case of the electromagnetic field interacting with matter. We considered the high temperature limit for the field, keeping arbitrary temperatures for each part of the volume elements of the material. We obtained a closed form for the Hadamard propagator, which let us study the dynamical evolution of the expectations values of the energy-momentum tensor components from the initial time. We showed that two contributions always take place in the transient evolution: one of these is associated to the material and the other one is only associated to the field. Transient features were studied and the long-time limit was derived in several cases. We proved that in the steady situation of a field in n + 1 dimensions, the material always contribute unless is non-dissipative. Conversely, the proper field contribution vanishes unless the material is non-dissipative or, moreover, at least for the 1 + 1 case, if there are regions without material. We conclude that any steady quantization scheme in 1 + 1 dimensions must consider both contributions and we argue why these results are physically expected from a dynamical point of view, and also could be valid for higher dimensions based on the expected continuity between the non-dissipative and real material cases.