Iosif B. Meyerov scite author profile

We review common extensions of particle-in-cell (PIC) schemes which account for strong field phenomena in laser-plasma interactions. After describing the physical processes of interest and their numerical implementation, we provide solutions for several associated methodological and algorithmic problems. We propose a modified event generator that precisely models the entire spectrum of incoherent particle emission without any low-energy cutoff, and which imposes close to the weakest possible demands on the numerical time step. Based on this, we also develop an adaptive event generator that subdivides the time step for locally resolving QED events, allowing for efficient simulation of cascades. Further, we present a new and unified technical interface for including the processes of interest in different PIC implementations. Two PIC codes which support this interface, PICADOR and ELMIS, are also briefly reviewed. CONTENTS

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Ultrabright GeV Photon Source via Controlled Electromagnetic Cascades in Laser-Dipole Waves

Gonoskov

et al. 2017

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One aim of upcoming high-intensity laser facilities [1][2][3] is to provide new high-flux gammaray sources [4]. Electromagnetic cascades [5-9] may serve for this, but are known to limit both field strengths and particle energies [10], restricting efficient production of photons to sub-GeV energies [11][12][13]. Here we show how to create a directed GeV photon source, enabled by a controlled interplay between the cascade and anomalous radiative trapping [14]. Using advanced 3D QED particle-in-cell (PIC) simulations [15] and analytic estimates, we show that the concept is feasible for planned [3] peak powers of 10 PW level. A higher peak power of 40 PW can provide 10 9 photons with GeV energies in a well-collimated 3 fs beam, achieving peak brilliance 9 × 10 24 ph s −1 mrad −2 mm −2 /0.1%BW. Such a source would be a powerful tool for studying fundamental electromagnetic [16] and nuclear processes [1, 17,18].Advances in high-intensity laser science offers opportunities for creating a new kind of high flux gamma-ray source, based on the use of strong laser fields to accelerate particles and stimulate emission within a single optical cycle [11-13, 19, 20]. However, from a naive consideration of particle dynamics one would expect particles to be expelled from the temporal and spatial regions which are optimal for energy gain (i.e. the electric field antinodes). Furthermore, for intensities above 10 24 W/cm 2 radiation losses prevent particles from reaching their potential maximum energy (during a single phase of acceleration). This limits the effective generation of photons to sub-GeV energies. [10,21] Our aim here is to find the optimal strategy for source creation. To do so we exploit the anomalous radiative trapping [14] (ART) of electrons and positrons in a dipole wave [22], the latter being the field configuration which provides the highest possible field strength for a given peak power arXiv:1610.06404v1 [physics.plasm-ph]

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Publisher's Note: Extended particle-in-cell schemes for physics in ultrastrong laser fields: Review and developments [Phys. Rev. E92, 023305 (2015)]

Gonoskov¹,

Bastrakov²,

Efimenko³

et al. 2015

Phys. Rev. E

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Particle-in-cell plasma simulation on heterogeneous cluster systems

Bastrakov

Donchenko

Gonoskov

et al. 2012

Journal of Computational Science

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Extreme plasma states in laser-governed vacuum breakdown

Efimenko

Bashinov

Bastrakov

et al. 2018

Sci Rep

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Triggering vacuum breakdown at laser facility is expected to provide rapid electron-positron pair production for studies in laboratory astrophysics and fundamental physics. However, the density of the produced plasma may cease to increase at a relativistic critical density, when the plasma becomes opaque. Here, we identify the opportunity of breaking this limit using optimal beam configuration of petawatt-class lasers. Tightly focused laser fields allow generating plasma in a small focal volume much less than λ3 and creating extreme plasma states in terms of density and produced currents. These states can be regarded to be a new object of nonlinear plasma physics. Using 3D QED-PIC simulations we demonstrate a possibility of reaching densities over 1025 cm−3, which is an order of magnitude higher than expected earlier. Controlling the process via initial target parameters provides an opportunity to reach the discovered plasma states at the upcoming laser facilities.

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Iosif B. Meyerov

Extended particle-in-cell schemes for physics in ultrastrong laser fields: Review and developments

Ultrabright GeV Photon Source via Controlled Electromagnetic Cascades in Laser-Dipole Waves

Publisher's Note: Extended particle-in-cell schemes for physics in ultrastrong laser fields: Review and developments [Phys. Rev. E92, 023305 (2015)]

Particle-in-cell plasma simulation on heterogeneous cluster systems

Extreme plasma states in laser-governed vacuum breakdown

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