Saved in:
Bibliographic Details
Main Authors: Franca, O. J., Spallek, Fabian, Giesen, Steffen M., Berger, Robert, Singer, Kilian, Aull, Stefan, Buhmann, Stefan Yoshi
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2412.18044
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866915392834764800
author Franca, O. J.
Spallek, Fabian
Giesen, Steffen M.
Berger, Robert
Singer, Kilian
Aull, Stefan
Buhmann, Stefan Yoshi
author_facet Franca, O. J.
Spallek, Fabian
Giesen, Steffen M.
Berger, Robert
Singer, Kilian
Aull, Stefan
Buhmann, Stefan Yoshi
contents We investigate how the quantum friction experienced by a polarizable atom moving with constant velocity parallel to a planar interface is modified when the latter consists of chiral or nonreciprocal media, with special focus on topological insulators. We use macroscopic quantum electrodynamics to obtain the velocity-dependent Casimir-Polder frequency shift and decay rate. These results are a generalization to matter with time-reversal symmetry breaking. We illustrate our findings by examining the nonretarded and retarded limits for five examples: a perfectly conducting mirror, a perfectly reflecting nonreciprocal mirror, a three-dimensional topological insulator, a perfectly reflecting chiral mirror and an isotropic chiral medium. We find different asymptotic power laws for all these materials. Interestingly, we find two bridges between chirality and nonreciprocity through the frequency shift that arise as a consequence of the magnetoelectric coupling. Namely, the position-dependent Casimir-Polder frequency shift for the nonreciprocal case depend on a geometric magnetic field associated with photoionization of chiral molecules, the Casimir-Polder depending on the velocities for the chiral case have the optical rotatory strength as the atomic response while those for the nonreciprocal case depend on an analog of the optical rotatory strength.
format Preprint
id arxiv_https___arxiv_org_abs_2412_18044
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Spectroscopic footprints of quantum friction in nonreciprocal and chiral media
Franca, O. J.
Spallek, Fabian
Giesen, Steffen M.
Berger, Robert
Singer, Kilian
Aull, Stefan
Buhmann, Stefan Yoshi
Quantum Physics
Mesoscale and Nanoscale Physics
We investigate how the quantum friction experienced by a polarizable atom moving with constant velocity parallel to a planar interface is modified when the latter consists of chiral or nonreciprocal media, with special focus on topological insulators. We use macroscopic quantum electrodynamics to obtain the velocity-dependent Casimir-Polder frequency shift and decay rate. These results are a generalization to matter with time-reversal symmetry breaking. We illustrate our findings by examining the nonretarded and retarded limits for five examples: a perfectly conducting mirror, a perfectly reflecting nonreciprocal mirror, a three-dimensional topological insulator, a perfectly reflecting chiral mirror and an isotropic chiral medium. We find different asymptotic power laws for all these materials. Interestingly, we find two bridges between chirality and nonreciprocity through the frequency shift that arise as a consequence of the magnetoelectric coupling. Namely, the position-dependent Casimir-Polder frequency shift for the nonreciprocal case depend on a geometric magnetic field associated with photoionization of chiral molecules, the Casimir-Polder depending on the velocities for the chiral case have the optical rotatory strength as the atomic response while those for the nonreciprocal case depend on an analog of the optical rotatory strength.
title Spectroscopic footprints of quantum friction in nonreciprocal and chiral media
topic Quantum Physics
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2412.18044