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Main Authors: Huang, Yen-Chieh, Peng, Luo-Hao, Shirvani, Hossein, Chen, Wen-Chi, Muthuramalingam, Karthickraj, Wang, Wei-Chih
Format: Preprint
Published: 2022
Subjects:
Online Access:https://arxiv.org/abs/2205.08741
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author Huang, Yen-Chieh
Peng, Luo-Hao
Shirvani, Hossein
Chen, Wen-Chi
Muthuramalingam, Karthickraj
Wang, Wei-Chih
author_facet Huang, Yen-Chieh
Peng, Luo-Hao
Shirvani, Hossein
Chen, Wen-Chi
Muthuramalingam, Karthickraj
Wang, Wei-Chih
contents A conventional free-electron laser is useful but large, driven by a beam with many relativistic electrons. Although, recently, keV electron beams have been used to excite broadband radiation from material chips, there remains a quest for a chip-size free-electron laser capable of emitting coherent radiation. Unfortunately, those keV emitters from electron microscopes or dielectric laser accelerator usually deliver a small current with discrete moving electrons separated by a distance of a few or tens of microns. To envisage a chip-size free-electron laser as a powerful research tool, we study in this paper achievable laser radiation from a single electron and an array of single electrons atop a nano-grating dielectric waveguide. In our study, thanks to the strong coupling between the electron and the guided wave in a structure with distributed feedback, a single 50-keV electron generates 1.5-um laser-like radiation at the Bragg resonance of a 31-um long silicon grating with a 400-nm thickness and 310-nm period. When driven by a train of single electrons repeating at 0.1 PHz, the nano-grating waveguide emits a strong laser radiation at the second harmonic of the excitation frequency. A discrete spectrum of Smith-Purcell radiation mediated by the waveguide modes is also predicted in theory and observed from simulation in the vacuum space above the grating waveguide. This study opens up the opportunity for applications requiring combined advantages from compact high-brightness electron and photon sources.
format Preprint
id arxiv_https___arxiv_org_abs_2205_08741
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Single-electron Nano-chip Free-electron Laser
Huang, Yen-Chieh
Peng, Luo-Hao
Shirvani, Hossein
Chen, Wen-Chi
Muthuramalingam, Karthickraj
Wang, Wei-Chih
Optics
Accelerator Physics
A conventional free-electron laser is useful but large, driven by a beam with many relativistic electrons. Although, recently, keV electron beams have been used to excite broadband radiation from material chips, there remains a quest for a chip-size free-electron laser capable of emitting coherent radiation. Unfortunately, those keV emitters from electron microscopes or dielectric laser accelerator usually deliver a small current with discrete moving electrons separated by a distance of a few or tens of microns. To envisage a chip-size free-electron laser as a powerful research tool, we study in this paper achievable laser radiation from a single electron and an array of single electrons atop a nano-grating dielectric waveguide. In our study, thanks to the strong coupling between the electron and the guided wave in a structure with distributed feedback, a single 50-keV electron generates 1.5-um laser-like radiation at the Bragg resonance of a 31-um long silicon grating with a 400-nm thickness and 310-nm period. When driven by a train of single electrons repeating at 0.1 PHz, the nano-grating waveguide emits a strong laser radiation at the second harmonic of the excitation frequency. A discrete spectrum of Smith-Purcell radiation mediated by the waveguide modes is also predicted in theory and observed from simulation in the vacuum space above the grating waveguide. This study opens up the opportunity for applications requiring combined advantages from compact high-brightness electron and photon sources.
title Single-electron Nano-chip Free-electron Laser
topic Optics
Accelerator Physics
url https://arxiv.org/abs/2205.08741