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1. Monitoring electron energies during FLASH irradiations

Author

Iain D. C. Tullis, Alexander Berne, Kristoffer Petersson, Borivoj Vojnovic, and R G Newman

Subjects
Paper, Materials science, Electrons, Electron, FLASH, Linear particle accelerator, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Optics, LINAC, Radiology, Nuclear Medicine and imaging, Computer Simulation, Irradiation, Radiometry, pre-clinical radiotherapy, Range (particle radiation), Radiological and Ultrasound Technology, dosimetry, business.industry, electron beam energy, radiobiology, 030220 oncology & carcinogenesis, Cathode ray, Physics::Accelerator Physics, Radio frequency, Particle Accelerators, business, pre-clinical irradiation, Monte Carlo Method, Energy (signal processing), Beam (structure)
Abstract

When relativistic electrons are used to irradiate tissues, such as during FLASH pre-clinical irradiations, the electron beam energy is one of the critical parameters that determine the dose distribution. Moreover, during such irradiations, linear accelerators (linacs) usually operate with significant beam loading, where a small change in the accelerator output current can lead to beam energy reduction. Optimisation of the tuning of the accelerator’s radio frequency system is often required. We describe here a robust, easy-to-use device for non-interceptive monitoring of potential variations in the electron beam energy during every linac macro-pulse of an irradiation run. Our approach monitors the accelerated electron fringe beam using two unbiased aluminium annular charge collection plates, positioned in the beam path and with apertures (5 cm in diameter) for the central beam. These plates are complemented by two thin annular screening plates to eliminate crosstalk and equalise the capacitances of the charge collection plates. The ratio of the charge picked up on the downstream collection plate to the sum of charges picked up on the both plates is sensitive to the beam energy and to changes in the energy spectrum shape. The energy sensitivity range is optimised to the investigated beam by the choice of thickness of the first plate. We present simulation and measurement data using electrons generated by a nominal 6 MeV energy linac as well as information on the design, the practical implementation and the use of this monitor.

Published
2021

2. High-dose femtosecond-scale gamma-ray beams for radiobiological applications

Author

C A McAnespie, M J V Streeter, M Rankin, P Chaudhary, S J McMahon, K M Prise, and G Sarri

Subjects
Paper, Photons, radiobiology, Radiological and Ultrasound Technology, Lasers, Radiobiology, inverse compton scattering, ultra-high dose-rate, Electrons, Radiology, Nuclear Medicine and imaging, FLASH, Particle Accelerators
Abstract

Objective. In the irradiation of living tissue, the fundamental physical processes involved in radical production typically occur on a timescale of a few femtoseconds. A detailed understanding of these phenomena has thus far been limited by the relatively long duration of the radiation sources employed, extending well beyond the timescales for radical generation and evolution. Approach. Here, we propose a femtosecond-scale photon source, based on inverse Compton scattering of laser-plasma accelerated electron beams in the field of a second scattering laser pulse. Main results. Detailed numerical modelling indicates that existing laser facilities can provide ultra-short and high-flux MeV-scale photon beams, able to deposit doses tuneable from a fraction of Gy up to a few Gy per pulse, resulting in dose rates exceeding 1013 Gy/s. Significance. We envisage that such a source will represent a unique tool for time-resolved radiobiological experiments, with the prospect of further advancing radio-therapeutic techniques.

Published
2022