Name: EARLY-CAREER RESEARCHERS IN MEDICAL APPLICATIONS @ CERN – SHORT TALKS
Start: 2021-08-26T15:00:00+02:00
End: 2021-08-26T16:00:00+02:00
Location: CERN

EARLY-CAREER RESEARCHERS IN MEDICAL APPLICATIONS @ CERN – SHORT TALKS

Thursday 26 August 2021 - 15:00

Monday 23 August 2021
Tuesday 24 August 2021
Wednesday 25 August 2021
Thursday 26 August 2021
15:00 Introduction - Manuela Cirilli (CERN)
Introduction
- Manuela Cirilli (CERN)
15:00 - 15:02
Room: 40/S2-A01 - Salle Anderson
15:02 NIMMS - Manuela Cirilli (CERN)
NIMMS
- Manuela Cirilli (CERN)
15:02 - 15:07
Room: 40/S2-A01 - Salle Anderson
15:07 GaToroid - Luca Bottura (CERN)
GaToroid
- Luca Bottura (CERN)
15:07 - 15:12
Room: 40/S2-A01 - Salle Anderson
15:12 Progress in GaToroid, a novel gantry for hadron therapy - Gianluca Vernassa (INFN e Universita Genova (IT)) Ariel Haziot (CERN)
Progress in GaToroid, a novel gantry for hadron therapy
- Gianluca Vernassa (INFN e Universita Genova (IT))
- Ariel Haziot (CERN)
15:12 - 15:52
Room: 40/S2-A01 - Salle Anderson The Gatoroid project aims to develop a new type of gantry for hadron therapy. The novel concept defined in 2017 by Luca Bottura uses the axis-symmetry from a toroidal field to bend the beam and deliver it to the patient from several directions. The magnetic field of this toroidal gantry is static and neither the magnets nor the patient need to be rotated. A single upstream vector magnet is used to kick the particles into the gantry with a proper angle, depending on the energy and the desired direction. Able to be scaled to different energies, this gantry design can be adapted for either protons, ion beams or electrons. The elimination of all rotating parts as well as the significant reduction of size, weight, and cost thanks to the use of superconductive magnets are a big step forward that has the potential to improve greatly hadron therapy facilities. It opens as well great opportunity and potential in the domain of FLASH therapy. In order to assess the technical feasibility of such a device, the research group has lately been focused on the development of a scaled down demonstrator magnet. Two versions are being built and will be tested: one with HTS and another with LTS as conductor. The advances on the mechanical design will be presented, starting from an ideal coil configuration and gradually introducing modifications to meet structural, operational and manufacturing requirements. The impact of the design changes on the magnet have been evaluated throughout, from both the structural and the electromagnetic point of view, and the numerical models involved will be shortly subjected to validation through experimental evidence. Finally the progress in the construction of these 2 magnets will be shown.