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Main Authors: Haga, Akihiro, Sato, Yoshi-hide, Fujiwara, Hana, Sakata, Dousatsu, Bolst, David, Simpson, Edward C., Guatelli, Susanna
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.19395
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author Haga, Akihiro
Sato, Yoshi-hide
Fujiwara, Hana
Sakata, Dousatsu
Bolst, David
Simpson, Edward C.
Guatelli, Susanna
author_facet Haga, Akihiro
Sato, Yoshi-hide
Fujiwara, Hana
Sakata, Dousatsu
Bolst, David
Simpson, Edward C.
Guatelli, Susanna
contents This study evaluates the accuracy of nuclear fragmentation simulations using a quantum molecular dynamics (QMD) model based on relativistic mean field (RMF) theory for an energy range of 50-400 MeV/u, relevant to hadron therapy. A total of 16 parameter sets within the RMF framework are assessed based on their ability to reproduce ground-state properties such as the mean squared radius and binding energy, as obtained in QMD simulations. Among these, the NS2 parameter set is identified as the most suitable for describing stable nuclei over a wide mass range, with the use of an adaptive Gaussian wave packet width. Fragmentation cross sections of carbon ion projectiles on light nuclei targets (H, C, O, Al, Ti, and Cu) are simulated at incident energies of 50, 95, 290, and 400 MeV/u and compared with experimental data. The results indicate that the RQMD.RMF model provides superior reproductions for fragmentation at lower energies (50 and 95 MeV/u) compared to the Light Ion QMD (LIQMD) model implemented in Geant4 version 11.2. At higher energies (290 and 400 MeV/u), the RQMD.RMF model performs comparably to the LIQMD. This study demonstrates that the RQMD.RMF model provides a reliable framework for analyzing nuclear fragmentation and holds potential for applications in the planning and quality assurance of hadron therapy.
format Preprint
id arxiv_https___arxiv_org_abs_2503_19395
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantum molecular dynamics model based on relativistic mean field theory for light nucleus fragmentation in hadron therapy
Haga, Akihiro
Sato, Yoshi-hide
Fujiwara, Hana
Sakata, Dousatsu
Bolst, David
Simpson, Edward C.
Guatelli, Susanna
Nuclear Theory
This study evaluates the accuracy of nuclear fragmentation simulations using a quantum molecular dynamics (QMD) model based on relativistic mean field (RMF) theory for an energy range of 50-400 MeV/u, relevant to hadron therapy. A total of 16 parameter sets within the RMF framework are assessed based on their ability to reproduce ground-state properties such as the mean squared radius and binding energy, as obtained in QMD simulations. Among these, the NS2 parameter set is identified as the most suitable for describing stable nuclei over a wide mass range, with the use of an adaptive Gaussian wave packet width. Fragmentation cross sections of carbon ion projectiles on light nuclei targets (H, C, O, Al, Ti, and Cu) are simulated at incident energies of 50, 95, 290, and 400 MeV/u and compared with experimental data. The results indicate that the RQMD.RMF model provides superior reproductions for fragmentation at lower energies (50 and 95 MeV/u) compared to the Light Ion QMD (LIQMD) model implemented in Geant4 version 11.2. At higher energies (290 and 400 MeV/u), the RQMD.RMF model performs comparably to the LIQMD. This study demonstrates that the RQMD.RMF model provides a reliable framework for analyzing nuclear fragmentation and holds potential for applications in the planning and quality assurance of hadron therapy.
title Quantum molecular dynamics model based on relativistic mean field theory for light nucleus fragmentation in hadron therapy
topic Nuclear Theory
url https://arxiv.org/abs/2503.19395