Litcius/Paper detail

Design and Magnetic Field Measurement of the Superconducting Magnets for the Next-Generation Rotating Gantry

Shigeki Takayama, Takashi Yazawa, Masafumi Asano, Masaaki Misawa, Yoshifumi Nagamoto, Saki Amano, Takahiro Orikasa, Yutaka Hirata, Takayuki Kanai, Sung Hyun Lee, Hikaru Souda, Takeo Iwai

2022IEEE Transactions on Applied Superconductivity28 citationsDOI

Abstract

This paper describes the design and reports the test results of the world's most compact rotating gantry for a heavy-ion therapy system mounted with superconducting bending and focusing magnets. A rotating gantry is cylindrical irradiation equipment with magnets for beam transport and beam scanning that delivers energetic carbon ions at up to 430 MeV/u precisely to a tumor from any direction without changing the posture of the patient. However, because of the high magnetic rigidity of therapeutic carbon ions, the rotating gantry was too big to be installed at general hospitals. Therefore, the superconducting rotating gantry had been developed in collaboration with Yamagata University. In the project, to achieve further downsizing of the rotating gantry, the length of the scanning irradiation system is reduced and the magnetic field of the superconducting magnet is increased to 3.5 T from the 2.88 T of the first superconducting gantry installed in the National Institutes for Quantum and Radiological Science and Technology (QST). As a result, the gantry is downsized to 2/3 of the first superconducting rotating gantry. This next-generation small superconducting rotating gantry has already been installed and is undergoing preclinical commissioning at Yamagata University.

Topics & Concepts

Superconducting magnetMagnetRigidity (electromagnetism)SuperconductivityLinear particle acceleratorPhysicsMagnetic fieldBeam (structure)Nuclear engineeringNuclear physicsNuclear magnetic resonanceOpticsCondensed matter physicsEngineeringQuantum mechanicsRadiation Therapy and DosimetryParticle accelerators and beam dynamicsParticle Accelerators and Free-Electron Lasers