Design and Verification of a Dielectric Laser Accelerator Test System for Sub-Relativistic Electrons

Ke Chen; Dandan Li; Ziyang Liu; Chenyi Yang; Bingheng Lu; Yadong Yang; Qianqian Wang

doi:10.1117/12.3035533

Design and Verification of a Dielectric Laser Accelerator Test System for Sub-Relativistic Electrons

Ke Chen, Dandan Li, Ziyang Liu, Chenyi Yang, Bingheng Lu, Yadong Yang, Qianqian Wang^*

^*Corresponding author for this work

School of Optics and Photonics

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Dielectric laser accelerators (DLAs) can achieve acceleration gradients that are 1 to 2 orders of magnitude higher than traditional radiofrequency (RF) accelerators. Due to the micrometer-scale dimensions of the DLA acceleration structure, on the one hand, high requirements are imposed on the quality of the electron beam and the alignment among the electron beam, driving laser, and DLA in experiments. On the other hand, although the DLA acceleration gradient is very high, the acceleration distance is insufficient, resulting in relatively small absolute energy gain for sub-relativistic electrons after DLA acceleration. These electrons are susceptible to interference from stray electromagnetic fields during propagation, posing significant challenges to the resolution and accuracy of sub-relativistic electron energy spectrum testing. Based on the principle of laser-driven grating-structure DLA for accelerating electron beams, this paper designs a complete test system, constructs electronic dynamics simulation models and magnetic field measurement electron energy spectrum simulation models for verification, designs a double-layer magnetic shunt to shield the interference of leakage magnetic fields on electrons in the simulation, considers factors such as the beam spot radius, divergence angle, and geomagnetic field intensity of the electron beam that conform to experimental conditions, and finally obtains simulated images of electron spots on the fluorescent screen after the electron beam is deflected by the magnetic field. The electron dynamics simulation results show that the electron beam achieves a maximum energy gain of 14.4401 keV over an acceleration length of 36 μm, with an acceleration gradient reaching 401.114 MeV/m. Based on the acceleration effect, a magnetic field of BB = 170 Gs is set, and an electron spot after deflection is obtained. The edges of the spots before and after acceleration are separated by Δd = 4.2889 mm, and the maximum energy gain measurement error is ϵΔE' = 4.45%, realizing precise measurement of the energy gain of sub-relativistic electrons.

Original language	English
Title of host publication	Nano-optoelectronics and Micro/Nano-photonics X
Editors	Zhiping Zhou, Kazumi Wada, Shaoliang Yu
Publisher	SPIE
ISBN (Electronic)	9781510682160
DOIs	https://doi.org/10.1117/12.3035533
Publication status	Published - 2024
Event	Nano-optoelectronics and Micro/Nano-photonics X 2024 - Nantong, China Duration: 13 Oct 2024 → 15 Oct 2024

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	13244
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Nano-optoelectronics and Micro/Nano-photonics X 2024
Country/Territory	China
City	Nantong
Period	13/10/24 → 15/10/24

Keywords

Dielectric laser accelerator
Energy gain
Energy spectrum measurement
Magnetic field deflection
Sub-relativistic electron

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10.1117/12.3035533

Cite this

Chen, K., Li, D., Liu, Z., Yang, C., Lu, B., Yang, Y., & Wang, Q. (2024). Design and Verification of a Dielectric Laser Accelerator Test System for Sub-Relativistic Electrons. In Z. Zhou, K. Wada, & S. Yu (Eds.), Nano-optoelectronics and Micro/Nano-photonics X Article 132440S (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13244). SPIE. https://doi.org/10.1117/12.3035533

@inproceedings{102dee84ae7a4b638fa888be1eba5154,

title = "Design and Verification of a Dielectric Laser Accelerator Test System for Sub-Relativistic Electrons",

abstract = "Dielectric laser accelerators (DLAs) can achieve acceleration gradients that are 1 to 2 orders of magnitude higher than traditional radiofrequency (RF) accelerators. Due to the micrometer-scale dimensions of the DLA acceleration structure, on the one hand, high requirements are imposed on the quality of the electron beam and the alignment among the electron beam, driving laser, and DLA in experiments. On the other hand, although the DLA acceleration gradient is very high, the acceleration distance is insufficient, resulting in relatively small absolute energy gain for sub-relativistic electrons after DLA acceleration. These electrons are susceptible to interference from stray electromagnetic fields during propagation, posing significant challenges to the resolution and accuracy of sub-relativistic electron energy spectrum testing. Based on the principle of laser-driven grating-structure DLA for accelerating electron beams, this paper designs a complete test system, constructs electronic dynamics simulation models and magnetic field measurement electron energy spectrum simulation models for verification, designs a double-layer magnetic shunt to shield the interference of leakage magnetic fields on electrons in the simulation, considers factors such as the beam spot radius, divergence angle, and geomagnetic field intensity of the electron beam that conform to experimental conditions, and finally obtains simulated images of electron spots on the fluorescent screen after the electron beam is deflected by the magnetic field. The electron dynamics simulation results show that the electron beam achieves a maximum energy gain of 14.4401 keV over an acceleration length of 36 μm, with an acceleration gradient reaching 401.114 MeV/m. Based on the acceleration effect, a magnetic field of BB = 170 Gs is set, and an electron spot after deflection is obtained. The edges of the spots before and after acceleration are separated by Δd = 4.2889 mm, and the maximum energy gain measurement error is ϵΔE' = 4.45%, realizing precise measurement of the energy gain of sub-relativistic electrons.",

keywords = "Dielectric laser accelerator, Energy gain, Energy spectrum measurement, Magnetic field deflection, Sub-relativistic electron",

author = "Ke Chen and Dandan Li and Ziyang Liu and Chenyi Yang and Bingheng Lu and Yadong Yang and Qianqian Wang",

note = "Publisher Copyright: {\textcopyright} 2024 SPIE.; Nano-optoelectronics and Micro/Nano-photonics X 2024 ; Conference date: 13-10-2024 Through 15-10-2024",

year = "2024",

doi = "10.1117/12.3035533",

language = "English",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Zhiping Zhou and Kazumi Wada and Shaoliang Yu",

booktitle = "Nano-optoelectronics and Micro/Nano-photonics X",

address = "United States",

}

Chen, K, Li, D, Liu, Z, Yang, C, Lu, B, Yang, Y & Wang, Q 2024, Design and Verification of a Dielectric Laser Accelerator Test System for Sub-Relativistic Electrons. in Z Zhou, K Wada & S Yu (eds), Nano-optoelectronics and Micro/Nano-photonics X., 132440S, Proceedings of SPIE - The International Society for Optical Engineering, vol. 13244, SPIE, Nano-optoelectronics and Micro/Nano-photonics X 2024, Nantong, China, 13/10/24. https://doi.org/10.1117/12.3035533

Design and Verification of a Dielectric Laser Accelerator Test System for Sub-Relativistic Electrons. / Chen, Ke; Li, Dandan; Liu, Ziyang et al.
Nano-optoelectronics and Micro/Nano-photonics X. ed. / Zhiping Zhou; Kazumi Wada; Shaoliang Yu. SPIE, 2024. 132440S (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13244).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Design and Verification of a Dielectric Laser Accelerator Test System for Sub-Relativistic Electrons

AU - Chen, Ke

AU - Li, Dandan

AU - Liu, Ziyang

AU - Yang, Chenyi

AU - Lu, Bingheng

AU - Yang, Yadong

AU - Wang, Qianqian

PY - 2024

Y1 - 2024

N2 - Dielectric laser accelerators (DLAs) can achieve acceleration gradients that are 1 to 2 orders of magnitude higher than traditional radiofrequency (RF) accelerators. Due to the micrometer-scale dimensions of the DLA acceleration structure, on the one hand, high requirements are imposed on the quality of the electron beam and the alignment among the electron beam, driving laser, and DLA in experiments. On the other hand, although the DLA acceleration gradient is very high, the acceleration distance is insufficient, resulting in relatively small absolute energy gain for sub-relativistic electrons after DLA acceleration. These electrons are susceptible to interference from stray electromagnetic fields during propagation, posing significant challenges to the resolution and accuracy of sub-relativistic electron energy spectrum testing. Based on the principle of laser-driven grating-structure DLA for accelerating electron beams, this paper designs a complete test system, constructs electronic dynamics simulation models and magnetic field measurement electron energy spectrum simulation models for verification, designs a double-layer magnetic shunt to shield the interference of leakage magnetic fields on electrons in the simulation, considers factors such as the beam spot radius, divergence angle, and geomagnetic field intensity of the electron beam that conform to experimental conditions, and finally obtains simulated images of electron spots on the fluorescent screen after the electron beam is deflected by the magnetic field. The electron dynamics simulation results show that the electron beam achieves a maximum energy gain of 14.4401 keV over an acceleration length of 36 μm, with an acceleration gradient reaching 401.114 MeV/m. Based on the acceleration effect, a magnetic field of BB = 170 Gs is set, and an electron spot after deflection is obtained. The edges of the spots before and after acceleration are separated by Δd = 4.2889 mm, and the maximum energy gain measurement error is ϵΔE' = 4.45%, realizing precise measurement of the energy gain of sub-relativistic electrons.

AB - Dielectric laser accelerators (DLAs) can achieve acceleration gradients that are 1 to 2 orders of magnitude higher than traditional radiofrequency (RF) accelerators. Due to the micrometer-scale dimensions of the DLA acceleration structure, on the one hand, high requirements are imposed on the quality of the electron beam and the alignment among the electron beam, driving laser, and DLA in experiments. On the other hand, although the DLA acceleration gradient is very high, the acceleration distance is insufficient, resulting in relatively small absolute energy gain for sub-relativistic electrons after DLA acceleration. These electrons are susceptible to interference from stray electromagnetic fields during propagation, posing significant challenges to the resolution and accuracy of sub-relativistic electron energy spectrum testing. Based on the principle of laser-driven grating-structure DLA for accelerating electron beams, this paper designs a complete test system, constructs electronic dynamics simulation models and magnetic field measurement electron energy spectrum simulation models for verification, designs a double-layer magnetic shunt to shield the interference of leakage magnetic fields on electrons in the simulation, considers factors such as the beam spot radius, divergence angle, and geomagnetic field intensity of the electron beam that conform to experimental conditions, and finally obtains simulated images of electron spots on the fluorescent screen after the electron beam is deflected by the magnetic field. The electron dynamics simulation results show that the electron beam achieves a maximum energy gain of 14.4401 keV over an acceleration length of 36 μm, with an acceleration gradient reaching 401.114 MeV/m. Based on the acceleration effect, a magnetic field of BB = 170 Gs is set, and an electron spot after deflection is obtained. The edges of the spots before and after acceleration are separated by Δd = 4.2889 mm, and the maximum energy gain measurement error is ϵΔE' = 4.45%, realizing precise measurement of the energy gain of sub-relativistic electrons.

KW - Dielectric laser accelerator

KW - Energy gain

KW - Energy spectrum measurement

KW - Magnetic field deflection

KW - Sub-relativistic electron

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U2 - 10.1117/12.3035533

DO - 10.1117/12.3035533

M3 - Conference contribution

AN - SCOPUS:85212447860

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Nano-optoelectronics and Micro/Nano-photonics X

A2 - Zhou, Zhiping

A2 - Wada, Kazumi

A2 - Yu, Shaoliang

PB - SPIE

T2 - Nano-optoelectronics and Micro/Nano-photonics X 2024

Y2 - 13 October 2024 through 15 October 2024

ER -

Design and Verification of a Dielectric Laser Accelerator Test System for Sub-Relativistic Electrons

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