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初步结果将“随机平均场”和“玻尔兹曼-朗之万单粒子”模型与 Geant4 耦合。

Preliminary results coupling "Stochastic Mean Field" and "Boltzmann-Langevin One Body" models with Geant4.

机构信息

Dip. Fisica, Sapienza Univ. di Roma, Rome, Italy; INFN Sezione di Roma, Rome, Italy.

SLAC National Accelerator Laboratory, Menlo Park, United States.

出版信息

Phys Med. 2019 Nov;67:116-122. doi: 10.1016/j.ejmp.2019.10.026. Epub 2019 Nov 6.

DOI:10.1016/j.ejmp.2019.10.026
PMID:31706147
Abstract

PURPOSE

Monte Carlo (MC) simulations are widely used for medical applications and nuclear reaction models are fundamental for the simulation of the particle interactions with patients in ion therapy. Therefore, it is of utmost importance to have reliable models in MC simulations for such interactions. Geant4 is one of the most used toolkits for MC simulation. However, its models showed severe limitations in reproducing the yields measured in the interaction of ion beams below 100 MeV/u with thin targets. For this reason, we interfaced two models, SMF ("Stochastic Mean Field") and BLOB ("Boltzmann-Langevin One Body"), dedicated to simulate such reactions, with Geant4.

METHODS

Both SMF and BLOB are semi-classical, one-body approaches to solve the Boltzmann-Langevin equation. They include an identical treatment of the mean-field propagation, on the basis of the same effective interaction, but they differ in the way fluctuations are included. Furthermore, we tested a correction to the excitation energy calculated for the light fragments emerging from the simulations and a simple coalescence model.

RESULTS

While both SMF and BLOB have been developed to simulate heavy ion interactions, they show very good results in reproducing the experimental yields of light fragments, up to alpha particles, obtained in the interaction of C with a thin carbon target at 62 MeV/u.

CONCLUSIONS

BLOB in particular gives promising results and this stresses the importance of integrating it into the Geant4 toolkit.

摘要

目的

蒙特卡罗(MC)模拟被广泛应用于医学领域,而核反应模型是模拟离子治疗中粒子与患者相互作用的基础。因此,在 MC 模拟中,这些相互作用需要有可靠的模型。Geant4 是最常用的 MC 模拟工具之一。然而,其模型在重现低于 100 MeV/u 的离子束与薄靶相互作用时的产额测量值方面存在严重的局限性。出于这个原因,我们将两个专门用于模拟此类反应的模型,即 SMF(“随机平均场”)和 BLOB(“玻尔兹曼-朗之万单一体”),与 Geant4 进行了接口。

方法

SMF 和 BLOB 都是半经典的、用于求解玻尔兹曼-朗之万方程的单一体方法。它们基于相同的有效相互作用,对平均场传播进行了相同的处理,但在包含波动的方式上有所不同。此外,我们还测试了对从模拟中出现的轻碎片的激发能计算的修正,以及一个简单的聚合模型。

结果

尽管 SMF 和 BLOB 都是为模拟重离子相互作用而开发的,但它们在重现 C 与薄碳靶在 62 MeV/u 相互作用时产生的轻碎片的实验产额方面表现非常好,直至阿尔法粒子。

结论

BLOB 尤其给出了有希望的结果,这强调了将其集成到 Geant4 工具包中的重要性。

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