Efficient computational modeling of electronic stopping power of organic polymers for proton therapy optimization

Matias, F.; Silva, T. F.; Koval, N. E.; Pereira, J. J. N.; Antunes, P. C. G.; Siqueira, P. T. D.; Tabacniks, M. H.; Yoriyaz, H.; Shorto, J. M. B.; Grande, P. L.

doi:10.1038/s41598-024-60651-0

Sci Rep

2024

DOI: 10.1038/s41598-024-60651-0

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Efficient computational modeling of electronic stopping power of organic polymers for proton therapy optimization

F. Matias,

T. F. Silva,

N. E. Koval

et al.

Abstract: This comprehensive study delves into the intricate interplay between protons and organic polymers, offering insights into proton therapy in cancer treatment. Focusing on the influence of the spatial electron density distribution on stopping power estimates, we employed real-time time-dependent density functional theory coupled with the Penn method. Surprisingly, the assumption of electron density homogeneity in polymers is fundamentally flawed, resulting in an overestimation of stopping power values at energie… Show more

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Cited by 2 publications

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Determining the stopping power of low kinetic energy Ne+ projectiles in self-Assembled monolayers

Alharbi,

Grande,

Köper

et al. 2024

Chemical Physics

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Determining the stopping power of low kinetic energy Ne+ projectiles in self-Assembled monolayers

Alharbi,

Grande,

Köper

et al. 2024

Chemical Physics

View full text Add to dashboard Cite

Deeper-band electron contributions to stopping power of silicon for low-energy ions

Matias,

Grande,

Koval

et al. 2024

The Journal of Chemical Physics

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This study provides accurate results for the electronic stopping cross sections of H, He, N, and Ne in silicon in low to intermediate energy ranges using various non-perturbative theoretical methods, including real-time time-dependent density functional theory, transport cross section, and induced-density approach. Recent experimental findings [Ntemou et al., Phys. Rev. B 107, 155145 (2023)] revealed discrepancies between the estimates of density functional theory and the observed values. We show that these discrepancies vanish by considering the nonuniform electron density of the deeper silicon bands for ion velocities approaching zero (v → 0). This indicates that mechanisms such as “elevator” and “promotion,” which can dynamically excite deeper-band electrons, are active, enabling a localized free-electron gas to emulate ion energy loss, as pointed out by Lim et al. [Phys. Rev. Lett. 116, 043201 (2016)]. The observation and the description of a velocity-proportionality breakdown in electronic stopping cross sections at very low velocities are considered to be a signature of the contributions of deeper-band electrons.

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Efficient computational modeling of electronic stopping power of organic polymers for proton therapy optimization

Cited by 2 publications

References 75 publications

Determining the stopping power of low kinetic energy Ne+ projectiles in self-Assembled monolayers

Determining the stopping power of low kinetic energy Ne+ projectiles in self-Assembled monolayers

Deeper-band electron contributions to stopping power of silicon for low-energy ions

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