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Main Authors: Chahshouri, Fatemeh, Talebi, Nahid
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2502.17183
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author Chahshouri, Fatemeh
Talebi, Nahid
author_facet Chahshouri, Fatemeh
Talebi, Nahid
contents The interaction between free electrons and laser-induced near-fields provides a platform to study ultrafast processes and quantum phenomena while enabling precise manipulation of electron wavefunctions through linear and orbital momentum transfer. Here, by introducing phase offset between two orthogonally polarized laser pulses exciting a gold nanorod, we generate a rotating plasmonic nearfield dipole with clockwise and counterclockwise circulating orientations and investigate its interaction with a slow electron beam. Our findings reveal that the circulation direction of plasmonic fields plays a crucial role in modulating electron dynamics, enhancing coupling strength, and controlling recoil. Furthermore, synchronizing the interaction time of the electron beam with rotational dipolar plasmonic resonances results in significant transfer of angular momenta to the electron beams and deflects the electron wavepackets from their original trajectory. These findings highlight the potential of plasmon rotors for shaping electron wavepackets, offering promising applications in ultrafast microscopy, spectroscopy, and quantum information processing.
format Preprint
id arxiv_https___arxiv_org_abs_2502_17183
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Ultrafast Plasmonic Rotors for Electron Beams
Chahshouri, Fatemeh
Talebi, Nahid
Optics
Quantum Physics
The interaction between free electrons and laser-induced near-fields provides a platform to study ultrafast processes and quantum phenomena while enabling precise manipulation of electron wavefunctions through linear and orbital momentum transfer. Here, by introducing phase offset between two orthogonally polarized laser pulses exciting a gold nanorod, we generate a rotating plasmonic nearfield dipole with clockwise and counterclockwise circulating orientations and investigate its interaction with a slow electron beam. Our findings reveal that the circulation direction of plasmonic fields plays a crucial role in modulating electron dynamics, enhancing coupling strength, and controlling recoil. Furthermore, synchronizing the interaction time of the electron beam with rotational dipolar plasmonic resonances results in significant transfer of angular momenta to the electron beams and deflects the electron wavepackets from their original trajectory. These findings highlight the potential of plasmon rotors for shaping electron wavepackets, offering promising applications in ultrafast microscopy, spectroscopy, and quantum information processing.
title Ultrafast Plasmonic Rotors for Electron Beams
topic Optics
Quantum Physics
url https://arxiv.org/abs/2502.17183