Hiroshi Iwase scite author profile

We have upgraded many features of the Particle and Heavy Ion Transport code System (PHITS) and released the new version as PHITS3.02. The accuracy and the applicable energy ranges of the code were greatly improved and extended, respectively, owing to the revisions to the nuclear reaction models and the incorporation of new atomic interaction models. Both condense history and track-structure methods were implemented to handle the electron and positron transport, although the latter is reliable only for simulations in liquid water. In addition, several usersupportive functions were developed, such as new tallies to efficiently obtain statistically better results, radioisotope source-generation function, and software tools useful for applying PHITS to medical physics. Owing to the continuous improvement and promotion of the code, the number of registered users has exceeded 3,000, and it is being used in diverse areas of study, including accelerator design, radiation shielding and protection, medical physics, and cosmic-ray research. In this paper, we summarize the basic features of PHITS3.02, especially those of the physics models and the functions implemented after the release of PHITS2.52 in 2013.

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Particle and Heavy Ion Transport code System, PHITS, version 2.52

Sato

Niita

Matsuda

et al. 2013

Journal of Nuclear Science and Technology

737

332

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An upgraded version of the Particle and Heavy Ion Transport code System, PHITS2.52, was developed and released to the public. The new version has been greatly improved from the previously released version, PHITS2.24, in terms of not only the code itself but also the contents of its package, such as the attached data libraries. In the new version, a higher accuracy of simulation was achieved by implementing several latest nuclear reaction models. The reliability of the simulation was improved by modifying both the algorithms for the electron-, positron-, and photon-transport simulations and the procedure for calculating the statistical uncertainties of the tally results. Estimation of the time evolution of radioactivity became feasible by incorporating the activation calculation program DCHAIN-SP into the new package. The efficiency of the simulation was also improved as a result of the implementation of shared-memory parallelization and the optimization of several time-consuming algorithms. Furthermore, a number of new user-support tools and functions that help users to intuitively and effectively perform PHITS simulations were developed and incorporated. Due to these improvements, PHITS is now a more powerful tool for particle transport simulation applicable to various research and development fields, such as nuclear technology, accelerator design, medical physics, and cosmic-ray research.

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PHITS—a particle and heavy ion transport code system

Niita

Sato

Iwase

et al. 2006

Radiation Measurements

345

213

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Experimental fragmentation studies with 12C therapy beams

Haettner¹,

Iwase²,

Schardt³

2006

116

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High-energy beams of (12)C ions in the range of 80-430 MeV u(-1) delivered by the heavy-ion synchrotron SIS-18 are used for radiotherapy of deep-seated localized tumors at the treatment unit at GSI Darmstadt. In order to improve the physical database, the fragmentation characteristics along the penetration path in tissue were investigated experimentally by using a water phantom as tissue-equivalent absorber. Measurements were performed at specific energies of 200 and 400 MeV u(-1) of the incident (12)C ions and at six different depths before and behind the Bragg peak. Secondary fragments with nuclear charges Z(f) = 1-5 were identified by scintillation detectors using DeltaE-E and time-of-flight techniques. The preliminary results include energy- and angular distributions, fragment yields, build-up curves and attenuation of the primary carbon projectiles.

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Experimental study of nuclear fragmentation of 200 and 400 MeV/u¹²C ions in water for applications in particle therapy

et al. 2013

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Carbon ion beams in the energy range of about 100-450 MeV/u offer excellent conditions for tumour therapy, in particular for the treatment of deep-seated radio-resistant tumours. Their depth-dose distribution is characterized by a low dose in the entrance channel, small lateral beam spread and an elevated biological effectiveness in the Bragg peak region. In comparison to protons the radiation field of heavier ions stopping in tissue is however more complex due to nuclear fragmentation reactions occurring along their stopping path. This results in an attenuation of the primary beam flux and a build-up of lower-Z fragments with longer ranges causing the characteristic dose tail beyond the Bragg peak. In the present work the characteristics of secondary charged particles at various depths of water were investigated experimentally using (12)C ion beams of 200 and 400 MeV/u delivered by the heavy-ion synchrotron SIS-18 at GSI Darmstadt. The nuclear charge Zf of secondary fragments was identified by combining energy loss and time-of-flight (TOF) measurements. Energy spectra and yields were recorded at lab angles of 0° - 10° and at seven different water depths corresponding to the entrance channel, the Bragg peak region and the tail of the Bragg curve.

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Hiroshi Iwase

Features of Particle and Heavy Ion Transport code System (PHITS) version 3.02

Particle and Heavy Ion Transport code System, PHITS, version 2.52

PHITS—a particle and heavy ion transport code system

Experimental fragmentation studies with 12C therapy beams

Experimental study of nuclear fragmentation of 200 and 400 MeV/u¹²C ions in water for applications in particle therapy

Contact Info

Product

Resources

About

Hiroshi Iwase

Features of Particle and Heavy Ion Transport code System (PHITS) version 3.02

Particle and Heavy Ion Transport code System, PHITS, version 2.52

PHITS—a particle and heavy ion transport code system

Experimental fragmentation studies with 12C therapy beams

Experimental study of nuclear fragmentation of 200 and 400 MeV/u12C ions in water for applications in particle therapy

Contact Info

Product

Resources

About

Experimental study of nuclear fragmentation of 200 and 400 MeV/u¹²C ions in water for applications in particle therapy