Ultra-intense laser pulses in near-critical underdense plasmas - Radiation reaction and energy partitioning

Erik Wallin; Arkady Gonoskov; Christopher Harvey; Olle Lundh; Mattias Marklund

doi:10.1017/S0022377817000320

Ultra-intense laser pulses in near-critical underdense plasmas - Radiation reaction and energy partitioning

Erik Wallin, Arkady Gonoskov, Christopher Harvey, Olle Lundh, Mattias Marklund

Atomic Physics

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

Abstract

Although, for current laser pulse energies, the weakly nonlinear regime of laser wakefield acceleration is known to be the optimal for reaching the highest possible electron energies, the capabilities of upcoming large laser systems will provide the possibility of running highly nonlinear regimes of laser pulse propagation in underdense or near-critical plasmas. Using an extended particle-in-cell (PIC) model that takes into account all the relevant physics, we show that such regimes can be implemented with external guiding for a relatively long distance of propagation and allow for the stable transformation of laser energy into other types of energy, including the kinetic energy of a large number of high energy electrons and their incoherent emission of photons. This is despite the fact that the high intensity of the laser pulse triggers a number of new mechanisms of energy depletion, which we investigate systematically.

Original language	English
Article number	905830208
Journal	Journal of Plasma Physics
Volume	83
Issue number	2
DOIs	https://doi.org/10.1017/S0022377817000320
Publication status	Published - 2017 Apr 1

Subject classification (UKÄ)

Fusion, Plasma and Space Physics

Free keywords

Plasma interactions
Plasma nonlinear phenomena
Plasma simulation

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10.1017/S0022377817000320

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abstract = "Although, for current laser pulse energies, the weakly nonlinear regime of laser wakefield acceleration is known to be the optimal for reaching the highest possible electron energies, the capabilities of upcoming large laser systems will provide the possibility of running highly nonlinear regimes of laser pulse propagation in underdense or near-critical plasmas. Using an extended particle-in-cell (PIC) model that takes into account all the relevant physics, we show that such regimes can be implemented with external guiding for a relatively long distance of propagation and allow for the stable transformation of laser energy into other types of energy, including the kinetic energy of a large number of high energy electrons and their incoherent emission of photons. This is despite the fact that the high intensity of the laser pulse triggers a number of new mechanisms of energy depletion, which we investigate systematically.",

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T1 - Ultra-intense laser pulses in near-critical underdense plasmas - Radiation reaction and energy partitioning

AU - Wallin, Erik

AU - Gonoskov, Arkady

AU - Harvey, Christopher

AU - Lundh, Olle

AU - Marklund, Mattias

PY - 2017/4/1

Y1 - 2017/4/1

N2 - Although, for current laser pulse energies, the weakly nonlinear regime of laser wakefield acceleration is known to be the optimal for reaching the highest possible electron energies, the capabilities of upcoming large laser systems will provide the possibility of running highly nonlinear regimes of laser pulse propagation in underdense or near-critical plasmas. Using an extended particle-in-cell (PIC) model that takes into account all the relevant physics, we show that such regimes can be implemented with external guiding for a relatively long distance of propagation and allow for the stable transformation of laser energy into other types of energy, including the kinetic energy of a large number of high energy electrons and their incoherent emission of photons. This is despite the fact that the high intensity of the laser pulse triggers a number of new mechanisms of energy depletion, which we investigate systematically.

AB - Although, for current laser pulse energies, the weakly nonlinear regime of laser wakefield acceleration is known to be the optimal for reaching the highest possible electron energies, the capabilities of upcoming large laser systems will provide the possibility of running highly nonlinear regimes of laser pulse propagation in underdense or near-critical plasmas. Using an extended particle-in-cell (PIC) model that takes into account all the relevant physics, we show that such regimes can be implemented with external guiding for a relatively long distance of propagation and allow for the stable transformation of laser energy into other types of energy, including the kinetic energy of a large number of high energy electrons and their incoherent emission of photons. This is despite the fact that the high intensity of the laser pulse triggers a number of new mechanisms of energy depletion, which we investigate systematically.

KW - Plasma interactions

KW - Plasma nonlinear phenomena

KW - Plasma simulation

U2 - 10.1017/S0022377817000320

DO - 10.1017/S0022377817000320

M3 - Article

AN - SCOPUS:85033783182

SN - 0022-3778

VL - 83

JO - Journal of Plasma Physics

JF - Journal of Plasma Physics

IS - 2

M1 - 905830208

ER -

Ultra-intense laser pulses in near-critical underdense plasmas - Radiation reaction and energy partitioning

Abstract

Subject classification (UKÄ)

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