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Journal Articles Physical Review Accelerators and Beams Year : 2022

Mechanisms to control laser-plasma coupling in laser wakefield electron acceleration

L. T. Dickson
Laboratoire de physique des gaz et des plasmas
C. I. D. Underwood
York Plasma Institute
F. Filippi
Agenzia Nazionale per le nuove Tecnologie, l’energia e lo sviluppo economico sostenibile = Italian National Agency for New Technologies, Energy and Sustainable Economic Development
R. J. Shalloo
Department of Physics-John Adams Institute
J. Björklund Svensson
Lund University [Lund]
D. Guénot
Lund University [Lund]
K. Svendsen
Physics department, Lund University
I. Moulanier
  • Function : Author
Laboratoire de physique des gaz et des plasmas
S. Dobosz Dufrénoy
  • Function : Author
Physique à Haute Intensité
C. D. Murphy
York Plasma Institute
N. C. Lopes
Instituto Superior Técnico, Universidade Técnica de Lisboa
P. P. Rajeev
  • Function : Author
STFC Rutherford Appleton Laboratory
Z. Najmudin
  • Function : Author
Department of Physics, Imperial College London, London SW7 2AZ, UK
G. Cantono
Physics department, Lund University
A. Persson
Physics department, Lund University
O. Lundh
Physics department, Lund University
G. Maynard
  • Function : Author
Laboratoire de physique des gaz et des plasmas
M. J. V. Streeter
  • Function : Author
Queens University Belfast
Imperial College London
B. Cros
Laboratoire de physique des gaz et des plasmas

Abstract

Experimental results, supported by precise modeling, demonstrate optimization of a plasma-based injector with intermediate laser pulse energy (<1 J), corresponding to a normalized vector potential a0 = 2.15, using ionization injection in a tailored plasma density profile. An increase in electron bunch quality and energy is achieved experimentally with the extension of the density downramp at the plasma exit. Optimization of the focal position of the laser pulse in the tailored plasma density profile is shown to efficiently reduce electron bunch angular deviation, leading to a better alignment of the electron bunch with the laser axis. Single peak electron spectra are produced in a previously unexplored regime by combining an early focal position and adaptive optic control of the laser wavefront by optimizing the symmetry of the prefocal laser energy distribution. Experimental results have been validated through particle-in-cell simulations using realistic laser energy, phase distribution, and temporal envelope, allowing for accurate predictions of difficult to model parameters, such as total charge and spatial properties of the electron bunches, opening the way for more accurate modeling for the design of plasma-based accelerators

Domains

Mechanics of materials [physics.class-ph] Physics [physics]
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Submitted on : Tuesday, October 18, 2022-4:23:44 PM

Last modification on : Friday, March 24, 2023-2:53:28 PM

Long-term archiving on: Thursday, January 19, 2023-6:57:52 PM

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Dates and versions

cea-03819515 , version 1 (18-10-2022)

Licence

Attribution - CC BY 4.0

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L. T. Dickson, C. I. D. Underwood, F. Filippi, R. J. Shalloo, J. Björklund Svensson, et al.. Mechanisms to control laser-plasma coupling in laser wakefield electron acceleration. Physical Review Accelerators and Beams, 2022, 25 (10), pp.101301. ⟨10.1103/PhysRevAccelBeams.25.101301⟩. ⟨cea-03819515⟩

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CEA CNRS IRAMIS-LIDYL CEA-UPSAY UNIV-PARIS-SACLAY UMR8578 IRAMIS GS-CHIMIE GS-PHYSIQUE
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