Measurement of absolute activation cross sections from carbon and aluminum for proton therapy

Abstract

This experimental study aims to measure nuclear cross sections from natC and 27Al which serve as reference targets regarding radioactivation in proton therapy. Graphite and aluminum foils were activated in broad, quasi-monochromatic proton fields generated with the pencil-beam scanning technique. The γ-emissions were analyzed subsequently in a nearby γ-ray spectrometry facility designed for low-level radioactivity measurements. The number of incident protons was measured with a Faraday Cup. A detailed evaluation of the uncertainties was performed.The cross section for the natC(p,x)11C reaction at 100 MeV is (70.2 ± 1.6 (sys.) ± 0.2 (stat.)) mb. The production cross sections from 27Al at 100 MeV are (19.9 ± 0.4 ± 0.3) mb for 22Na and (11.5±0.3±0.1) mb for 24Na. The systematic uncertainties contribute 2.0%–2.4% of the quoted uncertainties (k=1) of cross sections. Concluding, radioactivation cross sections were measured with proton fields in a clinically commissioned environment. The measured activation cross sections from aluminum used for monitoring of the proton fluence agree with the averaged values compiled in nuclear reaction data bases. For proton-induced radioactivation from carbon the chemical purity of the target strongly affects the experimental results. The cross section for the production of 11C derived from a measurement with a high-purity graphite target is in line with the largest cross section obtained in prior studies.