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Program Information

Design, Construction, and Installation of An Experimental Beam Line for the Development of MRI-Linac Compatible Electron Accelerator


B Whelan

B Whelan1*, P Keall1 , L Holloway2 , S Gierman3 , J Schmerge3 , S Tantawi3 , A Tremaine3 , A Trautwein3 , B Scott3 , R Fahrig4 , (1) University of Sydney, Sydney, ,(2) Liverpool Hospital and Ingham Institute, Liverpool, NSW, (3) Stanford Linear Accelerator Facility, Palo Alto, CA, (4) Siemens Healthcare GmbH, Forchheim,

Presentations

TU-H-BRA-7 (Tuesday, August 2, 2016) 4:30 PM - 6:00 PM Room: Ballroom A


Purpose:MRI guided radiation therapy (MRIgRT) is a rapidly growing field; however Linac operation in MRI fringe fields represents an ongoing challenge. We have previously shown in-silico that Linacs could be redesigned to function in the in-line orientation with no magnetic shielding by adopting an RF-gun configuration. Other authors have also published in-silico studies of Linac operation in magnetic fields; however to date no experimental validation data is published. This work details the design, construction, and installation of an experimental beam line to validate our in-silico results.

Methods:An RF-gun comprising 1.5 accelerating cells and capable of generating electron energies up to 3.2MeV is used. The experimental apparatus was designed to monitor both beam current (toroid current monitor), spot size (two phosphor screens with viewports), and generate peak magnetic fields of at least 1000G (three variable current electromagnetic coils). Thermal FEM simulations were developed to ensure coil temperature remained within 100degC. Other design considerations included beam disposal, vacuum maintenance, radiation shielding, earthquake safety, and machine protection interlocks.

Results:The beam line has been designed, built, and installed in a radiation shielded bunker. Water cooling, power supplies, thermo-couples, cameras, and radiation shielding have been successfully connected and tested. Interlock testing, vacuum processing, and RF processing have been successfully completed. The first beam on is expected within weeks. The coil heating simulations show that with care, peak fields of up to 1200G (320G at cathode) can be produced using 40A current, which is well within the fields expected for MRI-Linac systems. The maximum coil temperature at this current was 84degC after 6 minutes.

Conclusion:An experimental beam line has been constructed and installed at SLAC in order to experimentally characterise RF gun performance in in-line magnetic fields, validate in-silico design work, and provide the first published experimental data relating to accelerator functionality for MRIgRT.


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