Computationally efficient methods for modelling laser wakefield acceleration in the blowout regime

Cowan, B.; Kalmykov, Serguei Y.; Beck, Arnaud; Davoine, Xavier; Bunkers, K. J.; Lifschitz, Agustín; Lefebvre, E.; Bruhwiler, David L.; Shadwick, B. A.; Umstadter, Donald

doi:10.1017/s0022377812000517

Cited by 26 publications

(28 citation statements)

References 88 publications

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“…In any event, certain cases, such as bubble regime simulations or the modeling of a trapped bunch, require higher transverse resolution than that needed simply to resolve the plasma wavelength. Since increasing the longitudinal resolution is computationally impractical, this mandates a lower aspect ratio than p = , and the advantage of controlled dispersion is manifest [39].…”

Section: Linear Group Velocity Testsmentioning

confidence: 99%

Generalized algorithm for control of numerical dispersion in explicit time-domain electromagnetic simulations

Cowan

Bruhwiler

Cary

et al. 2013

Phys. Rev. ST Accel. Beams

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We describe a modification to the finite-difference time-domain algorithm for electromagnetics on a Cartesian grid which eliminates numerical dispersion error in vacuum for waves propagating along a grid axis. We provide details of the algorithm, which generalizes previous work by allowing 3D operation with a wide choice of aspect ratio, and give conditions to eliminate dispersive errors along one or more of the coordinate axes. We discuss the algorithm in the context of laser-plasma acceleration simulation, showing significant reduction-up to a factor of 280, at a plasma density of 10 23 m À3 -of the dispersion error of a linear laser pulse in a plasma channel. We then compare the new algorithm with the standard electromagnetic update for laser-plasma accelerator stage simulations, demonstrating that by controlling numerical dispersion, the new algorithm allows more accurate simulation than is otherwise obtained. We also show that the algorithm can be used to overcome the critical but difficult challenge of consistent initialization of a relativistic particle beam and its fields in an accelerator simulation.

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Section: Linear Group Velocity Testsmentioning

confidence: 99%

Generalized algorithm for control of numerical dispersion in explicit time-domain electromagnetic simulations

Cowan

Bruhwiler

Cary

et al. 2013

Phys. Rev. ST Accel. Beams

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“…Yet this process, apart from limiting the energy gain, destroys e-beam most assuredly if acceleration extends through the pulse depletion. (A plethora of evidence exists to this effect, both in laboratory experiments and numerical simulations [16,19,[22][23][24][25][38][39][40][41][42].) To enable a new generation of compact particle and radiation sources [43,44], one has to bypass the limitations this of scaling by designing an optical driver resilient to self-phase-modulation and self-compression.…”

Section: à3mentioning

confidence: 99%

Optically Controlled Laser-Plasma Electron Acceleration for Compact γ-Ray Sources

Kalmykov¹,

Davoine²,

Ghebregziabher³

et al. 2018

Accelerator Physics - Radiation Safety and Applications

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Thomson scattering (TS) from electron beams produced in laser-plasma accelerators may generate femtosecond pulses of quasi-monochromatic, multi-MeV photons. Scaling laws suggest that reaching the necessary GeV electron energy, with a percent-scale energy spread and five-dimensional brightness over 10 16 A/m 2 , requires acceleration in centimeter-length, tenuous plasmas (n 0 $ 10 17 cm À3 ), with petawatt-class lasers. Ultrahigh per-pulse power mandates single-shot operation, frustrating applications dependent on dosage. To generate high-quality near-GeV beams at a manageable average power (thus affording kHz repetition rate), we propose acceleration in a cavity ofelectrondensity ,drivenwithanincoherent stack of sub-Joule laser pulses through a millimeter-length, dense plasma (n 0 $ 10 19 cm À3). Blue-shifting one stack component by a considerable fraction of the carrier frequency compensates for the frequency red shift imparted by the wake. This avoids catastrophic self-compression of the optical driver and suppresses expansion of the accelerating cavity, avoiding accumulation of a massive low-energy background. In addition, the energy gain doubles compared to the predictions of scaling laws. Head-on collision of the resulting ultrabright beams with another optical pulse produces, via TS, gigawatt γ-ray pulses having a sub-20% bandwidth, over 10 6 photons in a microsteradian observation cone, and the observation cone, and the mean energy tunable up to 16 MeV.

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“…The feedback of the collective plasma motion onto the laser pulse leads to evolution of both the carrier frequency and the pulse envelope, [11][12][13][14][15][16][17][18] in turn, leaving its imprint on electron phase space. [19][20][21][22][23][24][25][26][27][28] The tight coupling of driver dynamics to the structure of the beam phase space offers great flexibility in tuning beam characteristics. Specific examples of this tunability, associated with the pulse transient dynamics in a finite-length plasma, have been recently observed in experiments.…”

Section: Introductionmentioning

confidence: 99%

Optical control of electron phase space in plasma accelerators with incoherently stacked laser pulsesa)

et al. 2015

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It is demonstrated that synthesizing an ultrahigh-bandwidth, negatively chirped laser pulse by incoherently stacking pulses of different wavelengths makes it possible to optimize the process of electron self-injection in a dense, highly dispersive plasma (n 0 $ 10 19 cm À3 ). Avoiding transformation of the driving pulse into a relativistic optical shock maintains a quasi-monoenergetic electron spectrum through electron dephasing and boosts electron energy far beyond the limits suggested by existing scaling laws. In addition, evolution of the accelerating bucket in a plasma channel is shown to produce a background-free, tunable train of femtosecond-duration, 35-100 kA, time-synchronized quasi-monoenergetic electron bunches. The combination of the negative chirp and the channel permits acceleration of electrons beyond 1 GeV in a 3 mm plasma with 1.4 J of laser pulse energy, thus offering the opportunity of high-repetition-rate operation at manageable average laser power. V C 2015 AIP Publishing LLC. [http://dx.

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Computationally efficient methods for modelling laser wakefield acceleration in the blowout regime

Cited by 26 publications

References 88 publications

Generalized algorithm for control of numerical dispersion in explicit time-domain electromagnetic simulations

Generalized algorithm for control of numerical dispersion in explicit time-domain electromagnetic simulations

Optically Controlled Laser-Plasma Electron Acceleration for Compact γ-Ray Sources

Optical control of electron phase space in plasma accelerators with incoherently stacked laser pulsesa)

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