Laser Generation of Near-GeV Low Emittance Positron Beams

Streeter, M. J. V.; Colgan, C.; Cavanagh, N.; Los, E.; Antoine, A. F.; Audet, T.; Balcazar, M. D.; L., Calvin,; Carderelli, J.; Ahmed, H.; Kettle, B.; Ma, Y.; Mangles, S. P. D.; Najmudin, Z.; Rajeev, P. P.; Symes, D. R.; Thomas, Alec; Sarri, G.

doi:10.48550/arxiv.2205.13850

Cited by 2 publications

(1 citation statement)

References 34 publications

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“…For instance, the scattering of a relativistic electron beam with a multi-PW laser pulse is predicted to generate gamma rays and electron-positron pairs (through nonlinear Compton scattering and Breit Wheeler pair creation [27]). Numerical studies have explored the potential for gamma-ray emission [28][29][30][31] and positron creation [32][33][34][35]. To date, only three schemes for positron creation and acceleration have been proposed [36][37][38].…”

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confidence: 99%

Creation and direct laser acceleration of positrons in a single stage

Martinez¹,

Barbosa²,

Vranic³

2022

Preprint

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Relativistic positron beams are required for fundamental research in nonlinear strong field QED, plasma physics, and laboratory astrophysics. Positrons are difficult to create and manipulate due to their short lifetime, and their energy gain is limited by the accelerator size in conventional facilities. Alternative compact accelerator concepts in plasmas are becoming more and more mature for electrons, but positron generation and acceleration remains an outstanding challenge. Here we propose a new setup where we can generate, inject and accelerate them in a single stage during the propagation of an intense laser in a plasma channel. The positrons are created from a laserelectron collision at 90 degrees, where the injection and guiding are made possible by an 800 nC electron beam loading which reverses the sign of the background electrostatic field. We obtain a 20 fC positron beam, with GeV-level central energy within 0.5 mm of plasma.

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confidence: 99%

Creation and direct laser acceleration of positrons in a single stage

Martinez¹,

Barbosa²,

Vranic³

2022

Preprint

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Characterization of relativistic electron–positron beams produced with laser-accelerated GeV electrons

Song

Kim

Won

et al. 2023

Sci Rep

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The characterization of an electron–positron beam generated from the interaction of a multi-GeV electron beam with a lead plate is performed using GEANT4 simulations. The dependence of the positron beam size on driver electron beam energy and lead converter thickness is investigated in detail. A pancake-like positron beam structure is generated with a monoenergetic multi-GeV driver electron beam, with the results indicating that a 5 GeV driver electron beam with 1 nC charge can generate a positron beam with a density of 1015–1016 cm−3 at one radiation length of lead. In addition, we find that electron–positron beams generated using above-GeV electron beams have neutralities greater than 0.3 at one radiation length of lead, whereas neutralities of 0.2 are observed when using a 200 MeV electron beam. The possibility of observing plasma instabilities in experiments is also examined by comparing the plasma skin depth with the electron–positron beam size. A quasi-neutral electron–positron plasma can be produced in the interaction between a 1 nC, 5 GeV electron beam and lead with a thickness of five radiation lengths. Our findings will aid in analyzing and interpreting laser-produced electron–positron plasma for laboratory astrophysics research.

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Laser Generation of Near-GeV Low Emittance Positron Beams

Cited by 2 publications

References 34 publications

Creation and direct laser acceleration of positrons in a single stage

Creation and direct laser acceleration of positrons in a single stage

Characterization of relativistic electron–positron beams produced with laser-accelerated GeV electrons

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