Nonlinear plasma wavelength scalings in a laser wakefield accelerator

H. Ding; A. Döpp; M. Gilljohann; J. Götzfried; S. Schindler; L. Wildgruber; G. Cheung; S. M. Hooker; S. Karsch

doi:10.1103/PhysRevE.101.023209

Nonlinear plasma wavelength scalings in a laser wakefield accelerator

H. Ding
, A. Döpp
, M. Gilljohann
, J. Götzfried
, S. Schindler
, L. Wildgruber
, G. Cheung
, S. M. Hooker
, S. Karsch

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

Abstract

Laser wakefield acceleration relies on the excitation of a plasma wave due to the ponderomotive force of an intense laser pulse. However, plasma wave trains in the wake of the laser have scarcely been studied directly in experiments. Here we use few-cycle shadowgraphy in conjunction with interferometry to quantify plasma waves excited by the laser within the density range of GeV-scale accelerators, i.e., a few 1018cm-3. While analytical models suggest a clear dependency between the nonlinear plasma wavelength and the peak potential a0, our study shows that the analytical models are only accurate for driver strength a01. Experimental data and systematic particle-in-cell simulations reveal that nonlinear lengthening of the plasma wave train depends not solely on the laser peak intensity but also on the waist of the focal spot.

Original language	English
Article number	023209
Journal	Physical Review E
Volume	101
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevE.101.023209
Publication status	Published - 1 Feb 2020
Externally published	Yes

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10.1103/PhysRevE.101.023209

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title = "Nonlinear plasma wavelength scalings in a laser wakefield accelerator",

abstract = "Laser wakefield acceleration relies on the excitation of a plasma wave due to the ponderomotive force of an intense laser pulse. However, plasma wave trains in the wake of the laser have scarcely been studied directly in experiments. Here we use few-cycle shadowgraphy in conjunction with interferometry to quantify plasma waves excited by the laser within the density range of GeV-scale accelerators, i.e., a few 1018cm-3. While analytical models suggest a clear dependency between the nonlinear plasma wavelength and the peak potential a0, our study shows that the analytical models are only accurate for driver strength a01. Experimental data and systematic particle-in-cell simulations reveal that nonlinear lengthening of the plasma wave train depends not solely on the laser peak intensity but also on the waist of the focal spot.",

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AU - Ding, H.

AU - Döpp, A.

AU - Gilljohann, M.

AU - Götzfried, J.

AU - Schindler, S.

AU - Wildgruber, L.

AU - Cheung, G.

AU - Hooker, S. M.

AU - Karsch, S.

PY - 2020/2/1

Y1 - 2020/2/1

N2 - Laser wakefield acceleration relies on the excitation of a plasma wave due to the ponderomotive force of an intense laser pulse. However, plasma wave trains in the wake of the laser have scarcely been studied directly in experiments. Here we use few-cycle shadowgraphy in conjunction with interferometry to quantify plasma waves excited by the laser within the density range of GeV-scale accelerators, i.e., a few 1018cm-3. While analytical models suggest a clear dependency between the nonlinear plasma wavelength and the peak potential a0, our study shows that the analytical models are only accurate for driver strength a01. Experimental data and systematic particle-in-cell simulations reveal that nonlinear lengthening of the plasma wave train depends not solely on the laser peak intensity but also on the waist of the focal spot.

AB - Laser wakefield acceleration relies on the excitation of a plasma wave due to the ponderomotive force of an intense laser pulse. However, plasma wave trains in the wake of the laser have scarcely been studied directly in experiments. Here we use few-cycle shadowgraphy in conjunction with interferometry to quantify plasma waves excited by the laser within the density range of GeV-scale accelerators, i.e., a few 1018cm-3. While analytical models suggest a clear dependency between the nonlinear plasma wavelength and the peak potential a0, our study shows that the analytical models are only accurate for driver strength a01. Experimental data and systematic particle-in-cell simulations reveal that nonlinear lengthening of the plasma wave train depends not solely on the laser peak intensity but also on the waist of the focal spot.

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DO - 10.1103/PhysRevE.101.023209

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Nonlinear plasma wavelength scalings in a laser wakefield accelerator

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