Litcius/Paper detail

The challenge of ionisation chamber dosimetry in ultra-short pulsed high dose-rate Very High Energy Electron beams

M. McManus, F. Romanò, N. D. Lee, W. Farabolini, Antonio Gilardi, Gary Royle, Hugo Palmans, Anna Subiel

2020Scientific Reports133 citationsDOIOpen Access PDF

Abstract

High dose-rate radiotherapy, known as FLASH, has been shown to increase the differential response between healthy and tumour tissue. Moreover, Very High Energy Electrons (VHEEs) provide more favourable dose distributions than conventional radiotherapy electron and photon beams. Plane-parallel ionisation chambers are the recommended secondary standard systems for clinical reference dosimetry of electrons, therefore chamber response to these high energy and high dose-per-pulse beams must be well understood. Graphite calorimetry, the UK primary standard, has been employed to measure the dose delivered from a 200 MeV pulsed electron beam. This was compared to the charge measurements of a plane-parallel ionisation chamber to determine the absolute collection efficiency and infer the ion recombination factor. The dose-per-pulse measured by the calorimeter ranged between 0.03 Gy/pulse and 5.26 Gy/pulse, corresponding to collection efficiencies between 97% and 4%, respectively. Multiple recombination models currently available have been compared with experimental results. This work is directly applicable to the development of standard dosimetry protocols for VHEE radiotherapy, FLASH radiotherapy and other high dose-rate modalities. However, the use of secondary standard ionisation chambers for the dosimetry of high dose-per-pulse VHEEs has been shown to require large corrections for charge collection inefficiency.

Topics & Concepts

DosimetryIonization chamberElectronIonizationDosimeterDose profileAbsorbed doseSecondary electronsCalorimeter (particle physics)Ionizing radiationMaterials scienceNuclear medicineAtomic physicsPhysicsOpticsNuclear physicsIrradiationIonMedicineDetectorQuantum mechanicsRadiation Therapy and DosimetryAdvanced Radiotherapy TechniquesRadiation Detection and Scintillator Technologies