Nonequilibrium Casimir-Polder Interaction Between Nanoparticles and Substrates Coated with Gapped Graphene

TL;DR

This paper investigates the nonequilibrium Casimir-Polder force between nanoparticles and substrates coated with gapped graphene, revealing how temperature differences and energy gaps influence the force magnitude.

Contribution

It introduces a formalism using the polarization tensor to calculate nonequilibrium Casimir-Polder forces involving gapped graphene coatings, highlighting the effects of temperature and energy gap variations.

Findings

Substrate coating increases force magnitude.

Higher substrate temperature amplifies the force.

Increasing energy gap reduces the force.

Abstract

The out-of-thermal-equilibrium Casimir-Polder force between nanoparticles and dielectric substrates coated with gapped graphene is considered in the framework of the Dirac model using the formalism of the polarization tensor. This is an example of physical phenomena violating the time-reversal symmetry. After presenting the main points of the used formalism, we calculate two contributions to the Casimir-Polder force acting on a nanoparticle on the source side of a fused silica glass substrate coated with gapped graphene, which is either cooler or hotter than the environment. The total nonequilibrium force magnitudes are computed as a function of separation for different values of the energy gap and compared with those from an uncoated plate and with the equilibrium force in the presence of graphene coating. According to our results, the presence of a substrate increases the magnitude of the nonequlibrium force. The force magnitude becomes larger with higher and smaller with lower temperature of the graphene-coated substrate as compared to the equilibrium force at the environmental temperature. It is shown that with increasing energy gap the magnitude of the nonequilibrium force becomes smaller, and the graphene coating makes a lesser impact on the force acting on a nanoparticle from the uncoated substrate. Possible applications of the obtained results are discussed.