Bremsstrahlung Gamma-Ray Source and Gamma Radiography Based on Laser-Triggered Electron Acceleration in the Regime of Relativistic Self-Trapping of Light

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...

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Bibliographic Details
Published inBulletin of the Lebedev Physics Institute Vol. 50; no. Suppl 7; pp. S815 - S820
Main Authors Lobok, M. G., Brantov, A. V., Bychenkov, V. Yu
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 01.10.2023
Springer Nature B.V
Subjects
Bremsstrahlung
Density
Electron acceleration
Electron beams
Energy conversion efficiency
Gamma ray sources
Lasers
Physics
Physics and Astronomy
Power sources
Radiation Generation
Radiation shielding
Radiography
Records & achievements
Relativistic effects
Spatial resolution
Trapping
high-power gamma-ray pulses
bremsstrahlung
laser electron source
deep gamma radiography
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Summary: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/cm 2 ) with good contrast (high spatial resolution).
ISSN:1068-3356
1934-838X
DOI:10.3103/S1068335623190132