Abstract
High-energy positrons and bright γ-ray sources are of great importance both in fundamental research and for practical applications. However, collimated GeV electron–positron pair jets and γ-ray flashes are still rarely produced in the laboratory. Here, we demonstrate that by irradiating a near-critical-density plasma channel with two 10 PW-scale laser pulses, highly directional GeV electron–positron pairs and bright γ-ray beams can be efficiently generated. Three-dimensional particle-in-cell simulations show the formation of GeV positron jets with high density (8×1021/ cm3), attosecond duration (400 as), and a divergence angle of 14°. Additionally, ultrabright [2×1025 photons s−1 mm−2 mrad−2 (0.1% bandwidth)−1] collimated attosecond (370 as) γ-ray flashes with a laser energy conversion efficiency of 5.6% are emitted. These features show the significant advantage of using a plasma channel as compared with a uniform plasma and thus open up new possibilities for a wide variety of applications.
Highlights
Since the discovery of the positron,1 much attention has been devoted to the study of positron sources and their applications in various areas,2,3 including fundamental physics, medicine, and industry
The pulse intensity is greatly enhanced in the plasma channel
Dense attosecond electrons are trapped by the intense pulse and accelerated to multi-GeV energies, so that energetic attosecond g rays are efficiently emitted via nonlinear Compton scattering (NCS)
Summary
Since the discovery of the positron, much attention has been devoted to the study of positron sources and their applications in various areas, including fundamental physics, medicine, and industry. Several laser facilities that are currently under development will deliver laser pulses with ultrahigh intensity of order 1023–1024 W/cm and power in the range 10–200 PW This should open up a new realm of possibilities for light–matter interactions in the radiation and quantumdominated regimes.. This should open up a new realm of possibilities for light–matter interactions in the radiation and quantumdominated regimes.14–17 For these proposed schemes, it has been shown that when the laser intensity is above 1023 W/cm, there will be significant production of dense high-energy positron sources via the multiphoton Breit–Wheeler (BW) process from various media, such as plasmas and relativistic electron beams.. We present a practical approach to generate collimated GeV positron beams and bright g-ray flashes at an achievable laser intensity of ;1022 W/cm by using a plasma channel. Such atto-beams of relativistic particles and X/g rays are of interest in diverse scientific and technological applications.
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