Dynamics of relativistic transparency and optical shuttering in expanding overdense plasmas

Palaniyappan, S.; Hegelich, B. M.; Wu, Haipeng; Jung, Daniel; Gautier, D. C.; Yin, L.; Albright, B. J.; Johnson, R. P.; Shimada, T.; Letzring, S.; Offermann, Dustin; Ren, Jun; Huang, Chengkun; Hörlein, Rainer; Dromey, B.; Fernández, Juan; Shah, Rahul

doi:10.1038/nphys2390

Cited by 183 publications

(161 citation statements)

References 37 publications

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“…the density at which its dynamics strongly affect the propagation of the laser pulse. 15,16 In fact this pair plasma almost completely absorbs the laser pulse. Consequently, the energy of the accelerated ions could be reduced by ∼ 50%.…”

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confidence: 99%

Ion acceleration with radiation pressure in quantum electrodynamic regimes

et al. 2017

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The radiation pressure of next generation high-intensity lasers could efficiently accelerate ions to GeV energies. However, nonlinear quantum-electrodynamic effects play an important role in the interaction of these lasers with matter. We show that these quantum-electrodynamic effects lead to the production of a critical density pair-plasma which completely absorbs the laser pulse and consequently reduces the accelerated ion energy and efficiency by 30-50%.

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confidence: 99%

Ion acceleration with radiation pressure in quantum electrodynamic regimes

et al. 2017

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“…As a 0 exceeds 2.0, the laser begins to penetrate beyond the (non-relativistic) critical density surface due to relativistic transparency. 21 Hole-boring 7 does not occur in this case due to the ultrashort pulse in all cases, and the laser pulse begins to penetrate only when the last few cycles of the main pulse are present on the nonrelativistic critical density surface. To further illustrate this, Fig.…”

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confidence: 99%

Particle-in-cell simulations of electron acceleration from relativistic interaction of mid-infrared laser interactions with near solid density matter

et al. 2017

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Advances in ultra-intense laser technology are enabling, for the first time, relativistic intensities at mid-infrared (mid-IR) wavelengths. Anticipating further experimental research in this domain, we present high-resolution two dimensional Particle-in-Cell (PIC) simulation results using the Large-Scale Plasma (LSP) code that explores intense mid-IR laser interactions with near solid density targets. We present the results of thirty PIC simulations over a wide range of intensities (0.03<a0<40) and wavelengths (λ= 780 nm, 3 μm, and 10 μm). Earlier studies [Orban et al., Phys. Plasmas 22, 023110 (2015) and Ngirmang et al., Phys. Plasmas 23, 043111 (2016)], limited to λ= 780 nm and a0∼1, identified super-ponderomotive electron acceleration in the laser specular direction for normal-incidence laser interactions with dense targets. We extend this research to mid-IR wavelengths and find a more general result that normal-incidence super-ponderomotive electron acceleration occurs provided that the laser intensity is not highly relativistic (a0≲1) and that the pre-plasma scale length is similar to or longer than the laser wavelength. Under these conditions, ejected electron angular and energy distributions are similar to expectations from an analytic model used in Ngirmang et al. [Phys. Plasmas 23, 043111 (2016)]. We also find that, for a0∼1, the mid-IR simulations exhibit a classic ponderomotive steepening pattern with multiple peaks in the ion and electron density distribution. Experimental validation of this basic laser-plasma interaction process should be possible in the near future using mid-IR laser technology and optical interferometry.

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“…17 Further appearing, for both RPA and BOA, is the possibility to more efficiently accelerate heavier ions and changes in the characteristics of the laser radiation that is transmitted or reflected from the target. 18,19 However, to distinguish and quantify the differences between the different acceleration mechanisms requires dedicated diagnostics. This is challenging to achieve, especially considering the often large angle of divergence of beams of laser accelerated ions of up to 40…”

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confidence: 99%

Diagnostics for studies of novel laser ion acceleration mechanisms

Senje

Yeung

Aurand

et al. 2014

Review of Scientific Instruments

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Diagnostic for investigating and distinguishing different laser ion acceleration mechanisms has been developed and successfully tested. An ion separation wide angle spectrometer can simultaneously investigate three important aspects of the laser plasma interaction: (1) acquire angularly resolved energy spectra for two ion species, (2) obtain ion energy spectra for multiple species, separated according to their charge to mass ratio, along selected axes, and (3) collect laser radiation reflected from and transmitted through the target and propagating in the same direction as the ion beam. Thus, the presented diagnostic constitutes a highly adaptable tool for accurately studying novel acceleration mechanisms in terms of their angular energy distribution, conversion efficiency, and plasma density evolution.

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Dynamics of relativistic transparency and optical shuttering in expanding overdense plasmas

Cited by 183 publications

References 37 publications

Ion acceleration with radiation pressure in quantum electrodynamic regimes

Ion acceleration with radiation pressure in quantum electrodynamic regimes

Particle-in-cell simulations of electron acceleration from relativistic interaction of mid-infrared laser interactions with near solid density matter

Diagnostics for studies of novel laser ion acceleration mechanisms

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