Relativistic Positron Creation Using Ultraintense Short Pulse Lasers

Chen, Hui; Wilks, S. C.; Bonlie, J.; Liang, Edison; Myatt, J. F.; Price, D.; Meyerhofer, D. D.; Beiersdörfer, P.

doi:10.1103/physrevlett.102.105001

Cited by 334 publications

(250 citation statements)

References 32 publications

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“…However, experiments and computer PIC modeling typically produce electrons with energies that are significantly higher than the non-injection limit (which of course varies with the corresponding a 0 ) 7,14,19,30 . Indeed, our PIC modeling also predicts electrons with greater energy than this limit (U e,max 200M eV , see FIG.…”

Section: Free Electron Interaction With a Lasermentioning

confidence: 99%

“…Over the last decade, laser facilities with peak intensity I > 10 20 W cm 2 have enabled the study of a variety of exciting applications including ion acceleration 1-3 , x-ray generation 4,5 , and laboratory astrophysics 6,7 . These applications are driven by the relativistic electron beams generated by ultraintense short pulse lasers interacting with plasma and, in general, are enhanced by maximizing the hot electron current and energies.…”

Section: Introductionmentioning

confidence: 99%

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On the origin of super-hot electrons from intense laser interactions with solid targets having moderate scale length preformed plasmas

Krygier¹,

Schumacher²,

Freeman³

2014

Physics of Plasmas

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We use particle-in-cell modeling to identify the acceleration mechanism responsible for the observed generation of super-hot electrons in ultra-intense laser-plasma interactions with solid targets with pre-formed plasma. We identify several features of direct laser acceleration (DLA) that drive the generation of super-hot electrons. We find that, in this regime, electrons that become super-hot are primarily injected by a looping mechanism that we call loop-injected direct acceleration (LIDA).

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Section: Free Electron Interaction With a Lasermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

On the origin of super-hot electrons from intense laser interactions with solid targets having moderate scale length preformed plasmas

Krygier¹,

Schumacher²,

Freeman³

2014

Physics of Plasmas

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show abstract

“…Magnetic reconnection of pair plasmas provides a unique opportunity to examine critically the fundamental reconnection physics due to the absence of Hall term, [3] which is generally thought to be the main mechanism for fast reconnection in electron-ion plasmas. Understanding of relativistic magnetic reconnection of pair plasmas will also provide useful physical insights for both new laboratory experiments of pair plasmas [4] and observations of the high energy Universe.…”

Section: Introductionmentioning

confidence: 99%

Particle energization in 3D magnetic reconnection of relativistic pair plasmas

Liu

Yin

et al. 2011

Physics of Plasmas

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We present large scale 3D particle-in-cell (PIC) simulations to examine particle energization in magnetic reconnection of relativistic electron-positron (pair) plasmas.The initial configuration is set up as a relativistic Harris equilibrium without a guide field. These simulations are large enough to accommodate a sufficient number of tearing and kink modes. Contrary to the non-relativistic limit, the linear tearing instability is faster than the linear kink instability, at least in our specific parameters.We find that the magnetic energy dissipation is first facilitated by the tearing instability and followed by the secondary kink instability. Particles are mostly energized inside the magnetic islands during the tearing stage due to the spatially varying electric fields produced by the outflows from reconnection. Secondary kink instability leads to additional particle acceleration. Accelerated particles are, however, observed to be thermalized quickly. The large amplitude of the vertical magnetic field resulting from the tearing modes by the secondary kink modes further help thermalizing the non-thermal particles generated from the secondary kink instability. Implications of these results for astrophysics are briefly discussed.

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“…They can be applied to various aspects such as target normal sheath acceleration of ions [16][17][18][19][20][21] , x/γ -ray emission [22] and generation of MeV-positron beams [23] . Both the cut-off energy and the population can be manipulated by adjusting the length and spatial period of the well-organized structures.…”

Section: Discussionmentioning

confidence: 99%

Exploring novel target structures for manipulating relativistic laser–plasma interaction

Jiang

Pukhov

et al. 2017

High Pow Laser Sci Eng

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The improved laser-to-pedestal contrast ratio enabled by current high-power laser pulse cleaning techniques allows the fine features of the target survive before the main laser pulse arrives. We propose to introduce the nano-fabrication technologies into laser-plasma interaction to explore the novel effects of micro-structures. We found out that not only laser-driven particle sources but also the laser pulse itself can be manipulated by specifically designed micro-cylinder and -tube targets, respectively. The proposal was supported by full-3D particle-in-cell simulations and successful proofof-principle experiments for the first time. We believe this would open a way to manipulate relativistic laser-plasma interaction at the micro-size level.

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Relativistic Positron Creation Using Ultraintense Short Pulse Lasers

Cited by 334 publications

References 32 publications

On the origin of super-hot electrons from intense laser interactions with solid targets having moderate scale length preformed plasmas

On the origin of super-hot electrons from intense laser interactions with solid targets having moderate scale length preformed plasmas

Particle energization in 3D magnetic reconnection of relativistic pair plasmas

Exploring novel target structures for manipulating relativistic laser–plasma interaction

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