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Development of a Compton Camera Prototype for Online Range Verification of Laser-Accelerated Proton Beams


K Parodi

PG Thirolf1 , S Aldawood1,2 , M Boehmer3 , J Bortfeldt1 , I Castelhano1,4 , R Gernhaeuser3 , H v.d. Kolff5 , C Lang1 , L Maier3 , DR Schaart5 , K Parodi1*, (1) Ludwig-Maximilians-University Munich, Garching, Germany, (2) King Saud University, Riyadh, Saudi Arabia, (3) Technical University Munich, Garching, Germany, (4) University of Lisbon, Portugal, (5) Delft University of Technology, The Netherlands

Presentations

SU-E-J-46 Sunday 3:00PM - 6:00PM Room: Exhibit Hall

Purpose: Development of a photon detection system designed for online range verification of laser-accelerated proton beams via prompt-gamma imaging of nuclear reactions.

Methods: We develop a Compton camera for the position-sensitive detection of prompt photons emitted from nuclear reactions between the proton beam and biological samples. The detector is designed to be capable to reconstruct the photon source origin not only from the Compton scattering kinematics of the primary photon, but also to allow for tracking of the Compton-scattered electrons.

Results: Simulation studies resulted in the design of the Compton camera based on a LaBr₃(Ce) scintillation crystal acting as absorber, preceded by a stacked array of 6 double-sided silicon strip detectors as scatterers. From the design simulations, an angular resolution of ≤ 2⁰ and an image reconstruction efficiency of 10⁻³ -10⁻⁵ (at 2-6 MeV) can be expected. The LaBr₃ crystal has been characterized with calibration sources, resulting in a time resolution of 273 ps (FWHM) and an energy resolution of about 3.8% (FWHM). Using a collimated (1 mm diameter) ¹³⁷Cs calibration source, the light distribution was measured for each of 64 pixels (6x6 mm²). Data were also taken with 0.5 mm collimation and 0.5 mm step size to generate a reference library of light distributions that allows for reconstructing the interaction position of the initial photon using a k-nearest neighbor (k-NN) algorithm developed by the Delft group.

Conclusion: The Compton-camera approach for prompt-gamma detection offers promising perspectives for ion beam range verification. A Compton camera prototype is presently being developed and characterized in Garching. Furthermore, an arrangement of, e.g., 4 camera modules could even be used in a ‘gamma-PET’ mode to detect delayed annihilation radiation from positron emitters in the irradiation interrupts (with improved performance in the presence of an additional third (prompt) photon (as in 10C and 14O).

Funding Support, Disclosures, and Conflict of Interest: This work was supported by the DFG Cluster of Excellence MAP (Munich-Centre for Advanced Photonics)


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