Monte Carlo modelling of a prototype small-body portable graphite calorimeter for ultra-high dose rate proton beams

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Monte Carlo modelling of a prototype small-body portable graphite calorimeter for ultra-high dose rate proton beams

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Cotterill, J; Flynn, S; Thomas, R; Subiel, A; Lee, N; Shipley, D; Palmans, H; Lourenco, A (2023) Monte Carlo modelling of a prototype small-body portable graphite calorimeter for ultra-high dose rate proton beams. Physics and Imaging in Radiation Oncology, 28. 100506

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Official URL: https://doi.org/10.1016/j.phro.2023.100506

Abstract

Background and purpose: Accurate dosimetry in Ultra-High Dose Rate (UHDR) beams is challenging because high levels of ion recombination occur within ionisation chambers used as reference dosimeters. A Small-body Portable Graphite Calorimeter (SPGC) exhibiting a dose-rate independent response was built to offer reduced uncertainty on secondary standard dosimetry in UHDR regimes. The aim of this study was to quantify the effect
of the geometry and material properties of the device on the dose measurement.

Materials and methods: A detailed model of the SPGC was built in the Monte Carlo code TOPAS (v3.6.1) to derive the impurity and gap correction factors, kimp and kgap. A dose conversion factor, DMCw/DMCg, was also calculated using FLUKA (v2021.2.0). These factors convert the average dose to its graphite core to the dose-to-water for a 249.7 MeV mono-energetic spot-scanned clinical proton beam. The effect of the surrounding Styrofoam on the dose measurement was examined in the simulations by substituting it for graphite.

Results: The kimp and kgap correction factors were 0.9993 ± 0.0002 and 1.0000 ± 0.0001, respectively when the Styrofoam was not substituted, and 1.0037 ± 0.0002 and 0.9999 ± 0.0001, respectively when substituted for graphite. The dose conversion factor was calculated to be 1.0806 ± 0.0001. All uncertainties are Type A.

Conclusions: Impurity and gap correction factors, and the dose conversion factor were calculated for the SPGC in a FLASH proton beam. Separating out the effect of scatter from Styrofoam insulation showed this as the dominating correction factor, amounting to 1.0043 ± 0.0002.

Item Type:	Article
Keywords:	Dosimetry; Proton; FLASH; UHDR; Monte Carlo; Calorimetry
Subjects:	Ionising Radiation > Dosimetry
Divisions:	Medical, Marine & Nuclear
Identification number/DOI:	10.1016/j.phro.2023.100506
Last Modified:	27 Sep 2024 14:22
URI:	https://eprintspublications.npl.co.uk/id/eprint/10065