Photon elastic scattering simulation: validation and improvements to Geant4

TL;DR

This paper evaluates and improves photon elastic scattering models in Geant4, identifying the most accurate model based on S-matrix calculations and highlighting the need for additional processes above 1 MeV for realistic simulations.

Contribution

It introduces and validates a new photon elastic scattering model based on second order S-matrix calculations for Geant4, enhancing simulation accuracy.

Findings

The S-matrix based model best reproduces experimental data.

Additional scattering processes are needed above 1 MeV.

Performance analysis of models is provided.

Abstract

Several models for the simulation of photon elastic scattering are quantitatively evaluated with respect to a large collection of experimental data retrieved from the literature. They include models based on the form factor approximation, on S-matrix calculations and on analytical parameterizations; they exploit publicly available data libraries and tabulations of theoretical calculations. Some of these models are currently implemented in general purpose Monte Carlo systems; some have been implemented and evaluated for the first time in this paper for possible use in Monte Carlo particle transport. The analysis mainly concerns the energy range between 5 keV and a few MeV. The validation process identifies the newly implemented model based on second order S-matrix calculations as the one best reproducing experimental measurements. The validation results show that, along with Rayleigh scattering, additional processes, not yet implemented in Geant4 nor in other major Monte Carlo systems, should be taken into account to realistically describe photon elastic scattering with matter above 1 MeV. Evaluations of the computational performance of the various simulation algorithms are reported along with the analysis of their physics capabilities.