Atomistic modelling and characterizaion of light sources based on small-amplitude short-period periodically bent crystals

TL;DR

This paper demonstrates the potential of gamma-ray light sources using ultrarelativistic electrons and positrons in periodically bent crystals, showing radiation enhancement and tunability through numerical modelling.

Contribution

It introduces a rigorous numerical model for SASP bent crystals and analyzes their radiation properties with realistic beam and crystal parameters.

Findings

Radiation brilliance can reach up to 10^{24} photons/s/mrad^2/mm^2/0.1BW.

Bending parameters significantly influence radiation spectra.

Enhanced gamma-ray emission observed in specific crystal and beam configurations.

Abstract

The feasibility of gamma-ray light sources based on the channeling phenomenon of ultrarelativistic electrons and positrons in oriented crystals that are periodically bent with Small Amplitude and Short Period (SASP) is demonstrated by means of rigorous numerical modelling that accounts for the interaction of a projectile with all atoms of the crystalline environment. Numerical data on the spectral distribution, brilliance, number of photons and power of radiation emitted by 10 GeV electron and positron beams passing through diamond, silicon and germanium crystals are presented and analyzed. The case studies presented in the paper refer to the FACET-II beams available at the SLAC facility. It is shown that the SASP bending gives rise to the radiation enhancement in the GeV photon energy range where the peak brilliance of radiation can be as high as on the 10^{24} photons/s/mrad^2/mm^2/0.1BW. The parameters of radiation can be tuned by varying the amplitude and period of bending.