On the improved performances of FLUKA v4-4.0 in out-of-field proton dosimetry

TL;DR

This study validates the improved proton nuclear elastic scattering model in FLUKA v4-4.0, demonstrating enhanced accuracy in out-of-field proton dose calculations in water phantoms compared to previous versions.

Contribution

The paper introduces and validates a new elastic scattering model in FLUKA v4-4.0, improving proton dosimetry simulations and highlighting the importance of accurate scattering physics.

Findings

FLUKA v4-4.0 shows better agreement with experimental dose measurements.

Proton elastic scattering significantly influences dose distribution in water.

Accurate beam and scattering geometry characterization is crucial for reliable simulations.

Abstract

A new model for the nuclear elastic scattering of protons below 250 MeV has been recently included in FLUKA v4-4.0, motivated by the evaluation of radiation effects in electronics. Nonetheless, proton nuclear elastic scattering plays a significant role also in proton dosimetry applications, for which the new model necessitated an explicit validation. Therefore, in this work a benchmark has been carried out against a recent measurement of radial-depth maps of absorbed dose in a water phantom under irradiation with protons of 100 MeV, 160 MeV, and 225 MeV. Two FLUKA versions have been employed to simulate these dose maps: v4-3.4, relying on a legacy model for proton nuclear elastic scattering, and v4-4.0, relying on the new model. The enhanced agreement with experimental absorbed doses obtained with FLUKA v4-4.0 is discussed, and the role played by proton nuclear elastic scattering, among other interaction mechanisms, in various regions of the radial-depth dose map is elucidated. Finally, the benchmark reported in this work is sensitive enough to showcase the importance of accurately characterizing beam parameters and the scattering geometry for Monte Carlo simulation purposes.