Saved in:
Bibliographic Details
Main Authors: Jakubec, Clemens, Solano, Pablo, Delić, Uroš, Sinha, Kanu
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2311.10496
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866911944932327424
author Jakubec, Clemens
Solano, Pablo
Delić, Uroš
Sinha, Kanu
author_facet Jakubec, Clemens
Solano, Pablo
Delić, Uroš
Sinha, Kanu
contents We analyze the radiative forces between two dielectric nanospheres mediated via the quantum and thermal fluctuations of the electromagnetic field in the presence of an external drive. We generalize the scattering theory description of fluctuation forces to include external quantum fields, allowing them to be in an arbitrary quantum state. The known trapping and optical binding potentials are recovered for an external coherent state. We demonstrate that an external squeezed vacuum state creates similar potentials to a laser, despite its zero average intensity. Moreover, Schrödinger cat states of the field can enhance or suppress the optical potential depending on whether they are odd or even. Considering the nanospheres trapped by optical tweezers, we examine the total interparticle potential as a function of various experimentally relevant parameters, such as the field intensity, polarization, and phase of the trapping lasers. We demonstrate that an appropriate set of parameters could produce mutual bound states of the two nanospheres with potential depth as large as $\sim200$ K. Our results are pertinent to ongoing experiments with trapped nanospheres in the macroscopic quantum regime, paving the way for engineering interactions among macroscopic quantum systems.
format Preprint
id arxiv_https___arxiv_org_abs_2311_10496
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Fluctuation-induced Forces on Nanospheres in External Fields
Jakubec, Clemens
Solano, Pablo
Delić, Uroš
Sinha, Kanu
Quantum Physics
We analyze the radiative forces between two dielectric nanospheres mediated via the quantum and thermal fluctuations of the electromagnetic field in the presence of an external drive. We generalize the scattering theory description of fluctuation forces to include external quantum fields, allowing them to be in an arbitrary quantum state. The known trapping and optical binding potentials are recovered for an external coherent state. We demonstrate that an external squeezed vacuum state creates similar potentials to a laser, despite its zero average intensity. Moreover, Schrödinger cat states of the field can enhance or suppress the optical potential depending on whether they are odd or even. Considering the nanospheres trapped by optical tweezers, we examine the total interparticle potential as a function of various experimentally relevant parameters, such as the field intensity, polarization, and phase of the trapping lasers. We demonstrate that an appropriate set of parameters could produce mutual bound states of the two nanospheres with potential depth as large as $\sim200$ K. Our results are pertinent to ongoing experiments with trapped nanospheres in the macroscopic quantum regime, paving the way for engineering interactions among macroscopic quantum systems.
title Fluctuation-induced Forces on Nanospheres in External Fields
topic Quantum Physics
url https://arxiv.org/abs/2311.10496