First application of a high-resolution silicon detector for proton beam Bragg peak detection in a 0.95 T magnetic field.

Abstract

To report on experimental results of a high spatial resolution silicon-based detector exposed to therapeutic quality proton beams in a 0.95T transverse magnetic field. These experimental results are important for the development of accurate and novel dosimetry methods in future potential real-time MRI-guided proton therapy systems. A permanent magnet device was utilized to generate a 0.95T magnetic field over a 4×20×15cm3 volume. Within this volume, a high-resolution silicon diode array detector was positioned inside a PMMA phantom of 4×15×12cm3 . This detector contains two orthogonal strips containing 505 sensitive volumes spaced at 0.2mm apart. Proton beams collimated to a circle of 10mm diameter with nominal energies of 90MeV, 110MeV, and 125MeV were incident on the detector from an edge-on orientation. This allows for a measurement of the Bragg peak at 0.2mm spatial resolution in both the depth and lateral profile directions. The impact of the magnetic field on the proton beams, that is, a small deflection was also investigated. A Geant4 Monte Carlo simulation was performed of the experimental setup to aid in interpretation of the results. The nominal Bragg peak for each proton energy was successfully observed with a 0.2mm spatial resolution in the 0.95T transverse magnetic field in both a depth and lateral profiles. The proton beam deflection (at 0.95T) was a consistent 2 ±0.5mm at the center of the magnetic volume for each beam energy. However, a pristine Bragg peak was not observed for each energy. This was caused by the detector packaging having small air gaps between layers of the phantom material surrounding the diode array. These air gaps act to degrade the shape of the Bragg peak, and further to this, the nonwater equivalent silicon chip acts to separate the Bragg peak into multiple peaks depending on the proton path taken. Overall, a promising performance of the silicon detector array was observed, however, with a qualitative assessment rather than a robust quantitative dosimetric evaluation at this stage of development. For the first time, a high-resolution silicon-based radiation detector has been used to measure proton beam Bragg peak deflections in a phantom due to a strong magnetic field. Future efforts are required to optimize the detector packaging to strengthen the robustness of the dosimetric quantities obtained from the detector. Such high-resolution silicon diode arrays may be useful in future efforts in MRI-guided proton therapy research.