Abstract

A major expense and design challenge in carbon/proton cancer therapy machines are the isocentric gantries. The transport elements of the carbon/proton gantry are presently made of standard conducting dipoles. Because of their large weight, of the order of $\ensuremath{\sim}100\text{ }\mathrm{\text{tons}}$, the total weight of the gantry with support structure is $\ensuremath{\sim}600\text{ }\mathrm{\text{tons}}$. The novel gantry design that is described here is made of fixed field superconducting magnets, thus dramatically reducing magnet size and weight compared to conventional magnets. In addition, the magnetic field is constant throughout the whole energy region required for tumor treatment. Particles make very small orbit offsets, passing through the beam line. The beam line is built of combined-function dipoles such as a nonscaling fixed field alternating gradient (NS-FFAG) structure. The very large momentum acceptance NS-FFAG comes from very strong focusing and very small dispersion. The NS-FFAG small magnets almost completely filled the beam line. They first make a quarter (or close to a quarter) of an arc bending upward and an additional half of a circle beam line finishing so that the beam is pointed towards the patient. At the end of the gantry, additional magnets with a fast response are required to allow radial scanning and to provide the required position and spot size. The fixed field combined-function magnets for the carbon gantry could be made of superconducting magnets by using low temperature superconducting cable or by using high temperature superconductors.

Highlights

  • The number of hadron cancer therapy facilities is continuously growing all around the world due to many advantages with respect to the already existing x-ray treatments

  • We describe the use of the principle of nonscaling fixed field alternating gradient (NS-FFAG), with very strong focusing and small dispersion, to obtain a new way of precisely transporting ions to the patients

  • The same gantry could be used for the proton therapy with kinetic energy range of 90 –250 MeV by adjusting magnetic field values for the momentum rigidity of B ˆ 1:870 87 T m

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Summary

INTRODUCTION

The number of hadron cancer therapy facilities is continuously growing all around the world due to many advantages with respect to the already existing x-ray treatments (using electron accelerators). The NS-FFAG concept provides reduction of the transport elements’ weight by 2 orders of magnitude to about 1.5 tons. This is accomplished due to very small orbit offsets within the magnets, about 13:6 mm. The presented gantry operates at fixed magnetic field for fully stripped carbon ions in the kinetic energy range of 150–400 MeV=u with magnets set for the momentum rigidity of B ˆ 4:882 T m. The same gantry could be used for the proton therapy with kinetic energy range of 90 –250 MeV by adjusting magnetic field values for the momentum rigidity of B ˆ 1:870 87 T m

THE NONSCALING FFAG
The basic cell of NS-FFAG gantry
Details of the gantry lattice design
Optimization of the gantry parameters
Matching of the gantry to the accelerator
Ray tracking in the gantry
Focusing and scanning magnets
Gantry magnets
CONCLUSIONS

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