High Average Gradient in a Laser-Gated Multistage Plasma Wakefield Accelerator

A. Knetsch; I. A. Andriyash; M. Gilljohann; O. Kononenko; A. Matheron; Y. Mankovska; P. San Miguel Claveria; V. Zakharova; E. Adli; S. Corde

doi:10.1103/PhysRevLett.131.135001

High Average Gradient in a Laser-Gated Multistage Plasma Wakefield Accelerator

A. Knetsch
, I. A. Andriyash
, M. Gilljohann
, O. Kononenko
, A. Matheron
, Y. Mankovska
, P. San Miguel Claveria
, V. Zakharova
, E. Adli
, S. Corde

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

Abstract

Plasma wakefield accelerators driven by particle beams are capable of providing accelerating gradient several orders of magnitude higher than currently used radio-frequency technology, which could reduce the length of particle accelerators, with drastic influence on the development of future colliders at TeV energies and the minimization of x-ray free-electron lasers. Since interplasma components and distances are among the biggest contributors to the total accelerator length, the design of staged plasma accelerators is one of the most important outstanding questions in order to render this technology instrumental. Here, we present a novel concept to optimize interplasma distances in a staged beam-driven plasma accelerator by drive-beam coupling in the temporal domain and gating the accelerator via a femtosecond ionization laser.

Original language	English
Article number	135001
Journal	Physical Review Letters
Volume	131
Issue number	13
DOIs	https://doi.org/10.1103/PhysRevLett.131.135001
Publication status	Published - 29 Sept 2023

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10.1103/PhysRevLett.131.135001

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title = "High Average Gradient in a Laser-Gated Multistage Plasma Wakefield Accelerator",

abstract = "Plasma wakefield accelerators driven by particle beams are capable of providing accelerating gradient several orders of magnitude higher than currently used radio-frequency technology, which could reduce the length of particle accelerators, with drastic influence on the development of future colliders at TeV energies and the minimization of x-ray free-electron lasers. Since interplasma components and distances are among the biggest contributors to the total accelerator length, the design of staged plasma accelerators is one of the most important outstanding questions in order to render this technology instrumental. Here, we present a novel concept to optimize interplasma distances in a staged beam-driven plasma accelerator by drive-beam coupling in the temporal domain and gating the accelerator via a femtosecond ionization laser.",

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doi = "10.1103/PhysRevLett.131.135001",

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AU - Knetsch, A.

AU - Andriyash, I. A.

AU - Gilljohann, M.

AU - Kononenko, O.

AU - Matheron, A.

AU - Mankovska, Y.

AU - San Miguel Claveria, P.

AU - Zakharova, V.

AU - Adli, E.

AU - Corde, S.

PY - 2023/9/29

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AB - Plasma wakefield accelerators driven by particle beams are capable of providing accelerating gradient several orders of magnitude higher than currently used radio-frequency technology, which could reduce the length of particle accelerators, with drastic influence on the development of future colliders at TeV energies and the minimization of x-ray free-electron lasers. Since interplasma components and distances are among the biggest contributors to the total accelerator length, the design of staged plasma accelerators is one of the most important outstanding questions in order to render this technology instrumental. Here, we present a novel concept to optimize interplasma distances in a staged beam-driven plasma accelerator by drive-beam coupling in the temporal domain and gating the accelerator via a femtosecond ionization laser.

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DO - 10.1103/PhysRevLett.131.135001

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ER -

High Average Gradient in a Laser-Gated Multistage Plasma Wakefield Accelerator

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