Saved in:
Bibliographic Details
Main Authors: Li, Yanzeng, Valenton, Emmanuel, Nagasamudram, Spoorthi, Parker, John, Perez, Marcos, Manna, Uttam, Biswas, Mahua, Rice, Stuart A., Scherer, Norbert F.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.09707
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910570194665472
author Li, Yanzeng
Valenton, Emmanuel
Nagasamudram, Spoorthi
Parker, John
Perez, Marcos
Manna, Uttam
Biswas, Mahua
Rice, Stuart A.
Scherer, Norbert F.
author_facet Li, Yanzeng
Valenton, Emmanuel
Nagasamudram, Spoorthi
Parker, John
Perez, Marcos
Manna, Uttam
Biswas, Mahua
Rice, Stuart A.
Scherer, Norbert F.
contents Optical trapping is having ever-increasing impact in science $-$ particularly biophysics, photonics and most recently in quantum optomechanics $-$ owing to its superior capability for manipulating nanoscale structures and materials. However, essentially all experimental optical trapping studies in the optical dipole regime have, to date, been dominated by the interaction between a material's electric polarizability, $α_{e}$, and the electric part of the incident electromagnetic field, and therefore described by electric field intensity gradient forces. Optical trapping based on optical magnetic light-matter interactions has not been experimentally addressed despite it's immediate extension of the boundaries of optical trapping research and applications. This paper addresses this long-standing deficiency through the realization of optical magnetic trapping of large index of refraction (i.e., Si) nanoparticles and also presents a formalism for quantitative understanding of the experimental findings. Our experimental optical trapping results require including optical magnetic polarizability, $α_{m}$, and electric-magnetic scattering forces associated with the Photonic Hall effect that are qualitatively and quantitatively validated by Maxwell stress tensor calculations. Our findings bring new opportunities for nanoparticle manipulation, potentially relax the limitations Ashkin claimed based on the optical Earnshaw's theorem, motivate optical matter formation by optical magnetic interactions, and suggest new N-body effects and symmetry breaking to drive dynamics of optical matter systems.
format Preprint
id arxiv_https___arxiv_org_abs_2408_09707
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle 0ptical trapping with optical magnetic field and photonic Hall effect forces
Li, Yanzeng
Valenton, Emmanuel
Nagasamudram, Spoorthi
Parker, John
Perez, Marcos
Manna, Uttam
Biswas, Mahua
Rice, Stuart A.
Scherer, Norbert F.
Optics
Applied Physics
Optical trapping is having ever-increasing impact in science $-$ particularly biophysics, photonics and most recently in quantum optomechanics $-$ owing to its superior capability for manipulating nanoscale structures and materials. However, essentially all experimental optical trapping studies in the optical dipole regime have, to date, been dominated by the interaction between a material's electric polarizability, $α_{e}$, and the electric part of the incident electromagnetic field, and therefore described by electric field intensity gradient forces. Optical trapping based on optical magnetic light-matter interactions has not been experimentally addressed despite it's immediate extension of the boundaries of optical trapping research and applications. This paper addresses this long-standing deficiency through the realization of optical magnetic trapping of large index of refraction (i.e., Si) nanoparticles and also presents a formalism for quantitative understanding of the experimental findings. Our experimental optical trapping results require including optical magnetic polarizability, $α_{m}$, and electric-magnetic scattering forces associated with the Photonic Hall effect that are qualitatively and quantitatively validated by Maxwell stress tensor calculations. Our findings bring new opportunities for nanoparticle manipulation, potentially relax the limitations Ashkin claimed based on the optical Earnshaw's theorem, motivate optical matter formation by optical magnetic interactions, and suggest new N-body effects and symmetry breaking to drive dynamics of optical matter systems.
title 0ptical trapping with optical magnetic field and photonic Hall effect forces
topic Optics
Applied Physics
url https://arxiv.org/abs/2408.09707