A Monte Carlo simulation framework for investigating the effect of inter-track coupling on H2O2 productions at ultra-high dose rates

Abstract

Background: Lower production of H2O2 in water is a hallmark of ultra-high dose rate (UHDR) compared to the conventional dose rate (CDR). However, the current computational models based on the predicted yield of H2O2 are in opposite of the experimental data. Methods: We construct an analytical model for the rate equation in the production of H2O2 from .OH-radicals and use it as a guide to propose a hypothetical geometrical inhomogeneity in the configuration of particles in the FLASH-UHDR beams. We perform a series of Monte Carlo (MC) simulations of the track structures for a system of charged particles impinging the medium in the form of clusters and/or bunches. Results: We demonstrate the interplay of diffusion, reaction rates, and overlaps in track-spacing attribute to a lower yield of H2O2 at FLASH-UHDR vs. CDR. This trend is reversed if spacing among the tracks becomes larger than a critical value, with a length scale that is proportional to the diffusion length of .OH-radicals modulated by a rate of decay due to recombination with other species, available within a track, and the space among the tracks. The latter is substantial on the suppressing of the H2O2 population at FLASH-UHDR relative to CDR. Conclusions: Based on our analysis of the present work, at FLASH-UHDR, the lower yield in H2O2 can be interpreted as a signature of bunching the particles in beams of ionizing radiation. The beams enter the medium in closely packed clusters and form inhomogeneities in the track-structure distribution. Thus the MC simulations based on the assumption of uniformly distributed tracks are unable to explain the experimental data.