Numerical studies of collinear laser-assisted injection from a foil for plasma wakefield accelerators

T.C. Wilson; J. Farmer; A. Pukhov; Z.-M. Sheng; B. Hidding

doi:10.1103/PhysRevAccelBeams.27.071301

Numerical studies of collinear laser-assisted injection from a foil for plasma wakefield accelerators

T.C. Wilson^*, J. Farmer, A. Pukhov, Z.-M. Sheng, B. Hidding

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

We present a laser-assisted electron injection scheme for beam-driven plasma wakefield acceleration. The laser is collinear with the driver and triggers the injection of hot electrons into the plasma wake by interaction with a thin solid target. We present a baseline case using the AWAKE Run 2 parameters and then perform variations on key parameters to explore the scheme. It is found that the trapped witness electron charge may be tuned by altering laser parameters, with a strong dependence on the phase of the wake upon injection. Normalized emittance settles at the order of micrometres and varies with witness charge. The scheme is robust to misalignment, with a 1/10th plasma skin-depth offset (20 μ⁢m for the AWAKE case) having a negligible effect on the final beam. The final beam quality is better than similar existing schemes, and several avenues for further optimization are indicated. The constraints on the AWAKE experiment are very specific, but the general principles of this mechanism can be applied to future beam-driven plasma wakefield accelerator experiments.

Original language	English
Article number	071301
Number of pages	7
Journal	Physical Review Accelerators and Beams
Volume	27
Issue number	7
DOIs	https://doi.org/10.1103/PhysRevAccelBeams.27.071301
Publication status	Published - 29 Jul 2024

Funding

The authors acknowledge the United Kingdom Science and Technology Facilities Council Grants No. ST/V001612/1, No. ST/T00195X/1, and No. ST/X006298/1. This work used computational resources of the National Energy Research Scientific Computing Center, which is supported by DOE DE-AC02-05CH11231.

Keywords

plasma acceleration and new acceleration techniques
laser wakefield accelerators
particle acceleration in plasmas
particle-in-cell

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10.1103/PhysRevAccelBeams.27.071301Licence: CC BY 4.0

Wilson-etal-PRAB-2024-Numerical-studies-of-collinear-laser-assisted-injectionFinal published version, 1.49 MBLicence: CC BY 4.0

2 Finished

Production of high quality electron bunches in AWAKE Run 2 2023-
McKenna, P. (Principal Investigator), Hidding, B. (Co-investigator) & Sheng, Z.-M. (Co-investigator)
STFC Science and Technology Facilities Council
1/04/22 → 31/03/25
Project: Research
Production of high quality electron bunches in AWAKE Run 2
McKenna, P. (Principal Investigator), Hidding, B. (Co-investigator) & Sheng, Z.-M. (Co-investigator)
STFC Science and Technology Facilities Council
1/10/20 → 31/03/24
Project: Research

Data For "Numerical studies of colinear laser-assisted injection from a foil as an alternate injection method"
Wilson, T. (Creator), University of Strathclyde, 12 Feb 2024
DOI: 10.15129/4266be87-5f01-4e92-a5ab-29333e58935b
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1 Citations
1 Presentation/Speech

Laser assisted injection from a foil
Wilson, T., 26 Apr 2023.
Research output: Contribution to conference › Presentation/Speech

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Cite this

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title = "Numerical studies of collinear laser-assisted injection from a foil for plasma wakefield accelerators",

abstract = "We present a laser-assisted electron injection scheme for beam-driven plasma wakefield acceleration. The laser is collinear with the driver and triggers the injection of hot electrons into the plasma wake by interaction with a thin solid target. We present a baseline case using the AWAKE Run 2 parameters and then perform variations on key parameters to explore the scheme. It is found that the trapped witness electron charge may be tuned by altering laser parameters, with a strong dependence on the phase of the wake upon injection. Normalized emittance settles at the order of micrometres and varies with witness charge. The scheme is robust to misalignment, with a 1/10th plasma skin-depth offset (20 μ⁢m for the AWAKE case) having a negligible effect on the final beam. The final beam quality is better than similar existing schemes, and several avenues for further optimization are indicated. The constraints on the AWAKE experiment are very specific, but the general principles of this mechanism can be applied to future beam-driven plasma wakefield accelerator experiments.",

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author = "T.C. Wilson and J. Farmer and A. Pukhov and Z.-M. Sheng and B. Hidding",

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doi = "10.1103/PhysRevAccelBeams.27.071301",

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AU - Wilson, T.C.

AU - Farmer, J.

AU - Pukhov, A.

AU - Sheng, Z.-M.

AU - Hidding, B.

PY - 2024/7/29

Y1 - 2024/7/29

N2 - We present a laser-assisted electron injection scheme for beam-driven plasma wakefield acceleration. The laser is collinear with the driver and triggers the injection of hot electrons into the plasma wake by interaction with a thin solid target. We present a baseline case using the AWAKE Run 2 parameters and then perform variations on key parameters to explore the scheme. It is found that the trapped witness electron charge may be tuned by altering laser parameters, with a strong dependence on the phase of the wake upon injection. Normalized emittance settles at the order of micrometres and varies with witness charge. The scheme is robust to misalignment, with a 1/10th plasma skin-depth offset (20 μ⁢m for the AWAKE case) having a negligible effect on the final beam. The final beam quality is better than similar existing schemes, and several avenues for further optimization are indicated. The constraints on the AWAKE experiment are very specific, but the general principles of this mechanism can be applied to future beam-driven plasma wakefield accelerator experiments.

AB - We present a laser-assisted electron injection scheme for beam-driven plasma wakefield acceleration. The laser is collinear with the driver and triggers the injection of hot electrons into the plasma wake by interaction with a thin solid target. We present a baseline case using the AWAKE Run 2 parameters and then perform variations on key parameters to explore the scheme. It is found that the trapped witness electron charge may be tuned by altering laser parameters, with a strong dependence on the phase of the wake upon injection. Normalized emittance settles at the order of micrometres and varies with witness charge. The scheme is robust to misalignment, with a 1/10th plasma skin-depth offset (20 μ⁢m for the AWAKE case) having a negligible effect on the final beam. The final beam quality is better than similar existing schemes, and several avenues for further optimization are indicated. The constraints on the AWAKE experiment are very specific, but the general principles of this mechanism can be applied to future beam-driven plasma wakefield accelerator experiments.

KW - plasma acceleration and new acceleration techniques

KW - laser wakefield accelerators

KW - particle acceleration in plasmas

KW - particle-in-cell

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DO - 10.1103/PhysRevAccelBeams.27.071301

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JF - Physical Review Accelerators and Beams

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ER -

Numerical studies of collinear laser-assisted injection from a foil for plasma wakefield accelerators

Abstract

Funding

Keywords

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Projects

Production of high quality electron bunches in AWAKE Run 2 2023-

Production of high quality electron bunches in AWAKE Run 2

Datasets

Data For "Numerical studies of colinear laser-assisted injection from a foil as an alternate injection method"

Research output

Laser assisted injection from a foil

Cite this