Strongly Mismatched Regime of Nonlinear Laser-Plasma Acceleration: Optimization of Laser-to-Energetic Particle Efficiency

Laser electron accelerators utilize a bubble regime of nonlinear plasma waves driven as laser wakefields that, from theoretical considerations, require a matched laser spot size incident on plasma. A strongly mismatched regime of nonlinear laser-plasma acceleration in the bubble regime, favored by e...

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Bibliographic Details
Published in:IEEE transactions on plasma science 2019-06, Vol.47 (6), p.2847-2858
Main Author: Sahai, Aakash A.
Format: Article
Language:English
Subjects:
Acceleration
Bubbles
Computer simulation
Electron accelerators
Elongation
Emittance
Energetic particles
Energy efficiency
Ion charge
Laser beams
Laser modes
Laser theory
Lasers
Mathematical model
Optimization
Particle accelerators
Particle beams
Particle energy
Particle in cell technique
Plasma acceleration
plasma accelerators
Plasma bubbles
plasma simulations
plasma wave
Plasma waves
Plasmas
positrons
Spectral emittance
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Summary:Laser electron accelerators utilize a bubble regime of nonlinear plasma waves driven as laser wakefields that, from theoretical considerations, require a matched laser spot size incident on plasma. A strongly mismatched regime of nonlinear laser-plasma acceleration in the bubble regime, favored by experiments, is introduced and modeled for optimization of laser-to-particle energy efficiency with application to the recently proposed laser positron accelerator. Strong mismatch, in contrast with the matched condition, arises from the incident laser spot size being much larger than that needed for equilibration of the laser ponderomotive and electron-ion charge-separation forces in the nonlinearly driven density structure of a plasma bubble. This is shown to be favorable for optimization of large self-injected electron charge and ultralow transverse emittance without precluding beam spectral shaping. It is shown that there are prominent signatures of the mismatched regime, strong optical-shock excitation, and bubble elongation, which are validated using multidimensional particle-in-cell simulations. This paper thus uncovers a generalized regime that apart from being used in many laser-plasma acceleration experiments also opens a novel pathway for a wide range of future applications.
ISSN:0093-3813
1939-9375
DOI:10.1109/TPS.2019.2914896