Analytical model for ion stopping power and range in the therapeutic energy interval for beams of hydrogen and heavier ions
Many different approaches exist to calculate stopping power and range of protons and heavy charged particles. These methods may be broadly categorized as physically complete theories (widely applicable and complex) or semi-empirical approaches (narrowly applicable and simple). However, little attention has been paid in the literature to approaches that are both widely applicable and simple. We developed simple analytical models of stopping power and range for ions of hydrogen, carbon, iron, and uranium that spanned intervals of ion energy from 351 keV u-1 to 450 MeV u-1 or wider. The analytical models typically reproduced the best-available evaluated stopping powers within 1% and ranges within 0.1 mm. The computational speed of the analytical stopping power model was 28% faster than a full-theoretical approach. The calculation of range using the analytic range model was 945 times faster than a widely-used numerical integration technique. The results of this study revealed that the new, simple analytical models are accurate, fast, and broadly applicable. The new models require just 6 parameters to calculate stopping power and range for a given ion and absorber. The proposed model may be useful as an alternative to traditional approaches, especially in applications that demand fast computation speed, small memory footprint, and simplicity.
Publication Source (Journal or Book title)
Physics in Medicine and Biology
Donahue, W., Newhauser, W., & Ziegler, J. (2016). Analytical model for ion stopping power and range in the therapeutic energy interval for beams of hydrogen and heavier ions. Physics in Medicine and Biology, 61 (17), 6570-6584. https://doi.org/10.1088/0031-9155/61/17/6570