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Bibliographic Details
Main Authors: Karakhanyan, Vage, Grosjean, Thierry
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2404.03738
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author Karakhanyan, Vage
Grosjean, Thierry
author_facet Karakhanyan, Vage
Grosjean, Thierry
contents Research at the frontier between optics and magnetism is revealing a wealth of innovative phenomena and avenues of exploration. Optical waves are demonstrating the capacity to induce ultrafast magnetism, while optical analogs of magnetic states, such as magnetic skyrmions, offer the prospect of novel spin-optical states. In this paper, we strengthen the synergy between light and magnetism by exploring the ability of plasmonic Neel skyrmions to create a stationary magnetic field within a thin gold film. We show that, when generated using a focused radially-polarized vortex beam, a plasmonic Neel skyrmion emerges as an optimum for inducing optomagnetism in a thin gold film. Optical skyrmions offer new degrees of freedom for enhancing and controlling optomagnetism in plasmonic nanostructures, with direct application in all-optical magnetization switching, magnetic recording, and the excitation of spin waves.
format Preprint
id arxiv_https___arxiv_org_abs_2404_03738
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optomagnetism with plasmonic skyrmion
Karakhanyan, Vage
Grosjean, Thierry
Optics
Research at the frontier between optics and magnetism is revealing a wealth of innovative phenomena and avenues of exploration. Optical waves are demonstrating the capacity to induce ultrafast magnetism, while optical analogs of magnetic states, such as magnetic skyrmions, offer the prospect of novel spin-optical states. In this paper, we strengthen the synergy between light and magnetism by exploring the ability of plasmonic Neel skyrmions to create a stationary magnetic field within a thin gold film. We show that, when generated using a focused radially-polarized vortex beam, a plasmonic Neel skyrmion emerges as an optimum for inducing optomagnetism in a thin gold film. Optical skyrmions offer new degrees of freedom for enhancing and controlling optomagnetism in plasmonic nanostructures, with direct application in all-optical magnetization switching, magnetic recording, and the excitation of spin waves.
title Optomagnetism with plasmonic skyrmion
topic Optics
url https://arxiv.org/abs/2404.03738