Characterization of a Gd-based color CMOS detector for proton dosimetry

Abstract

A color scintillation detector for relative dose distribution measurement was developed at PSI. The system consists of a gadolinium-based scintillating screen mounted perpendicularly to the beam axis and coupled with a color CMOS camera in a light-tight box. The camera is equipped with an iris (aperture) controller to remotely adjust the number of photons reaching the image sensor. To improve the measurement accuracy and decrease the image artifacts, we investigated different methods for spatial calibration and optimized the internal light reflection by adjusting the detector structure. The response dependence on camera working distance, iris setting, and color channels was assessed. The depth-dose curves of the gadolinium-based scintillator in three RGB channels were compared with reference curves measured by an Advanced Markus plane-parallel ion chamber. The quenching effect of the ▪ screen measured with this system amounts to about 10% in the Bragg peak region of a 150 MeV proton beams. The shape of the emission spectrum was observed to be independent of the ionization density. Preliminary investigations showed that it is possible to correlate the ratio of the detector response in different color channels with the proton ionization density.