Abstract
The XCELS [1] infrastructure is capable of providing a breakthrough in creating a record-breaking high-power source of gamma radiation using laser-accelerated electron beams, which is substantiated by the numerical simulation of the action of a short XCELS laser pulse on low-density targets, and by calculating the bremsstrahlung generated by an electron bunch in a converter target to produce a high-power gamma-ray pulse. The high efficiency of generating a record number of multi-MeV gamma quanta with a huge peak gamma flux is due to the use of relativistic self-trapping of a laser pulse as a driver of such wakefield acceleration of electrons, which ensures the achievement of a maximum charge of electrons accelerated to a multi-MeV level and a maximum conversion efficiency of laser energy in near-critical density targets. The possibility of converting up to 8% of laser energy into the energy of a beam of gamma-ray quanta (with an energy of more than 1 MeV) and the prospects for using the resulting source for deep gamma radiography in a single laser shot are demonstrated. The latter is also substantiated by a numerical experiment on obtaining gamma-ray images of dense hidden objects with a currently record-breaking shielding thickness (up to 400 mm of iron, which corresponds to a linear density of 320 g/cm2) with good contrast (high spatial resolution).
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The work was supported by the scientific program of the National Center for Physics.
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Translated by I. Ulitkin
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Lobok, M.G., Brantov, A.V. & Bychenkov, V.Y. Bremsstrahlung Gamma-Ray Source and Gamma Radiography Based on Laser-Triggered Electron Acceleration in the Regime of Relativistic Self-Trapping of Light. Bull. Lebedev Phys. Inst. 50 (Suppl 7), S815–S820 (2023). https://doi.org/10.3103/S1068335623190132
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DOI: https://doi.org/10.3103/S1068335623190132