Your search keyword '"Roesler S."' showing total 5 results

1. Characterization of the PTW 34031 ionization chamber (PMI) at RCNP with high energy neutrons ranging from 100 – 392 MeV

Author

Theis C., Carbonez P., Feldbaumer E., Forkel-Wirth D., Jaegerhofer L., Pangallo M., Perrin D., Urscheler C., Roesler S., Vincke H., Widorski M., Iwamoto Y., Hagiwara M., Satoh D., Iwase H., Yashima H., Matsumoto T., Masuda A., Nishiyama J., Harano H., Itoga T., Nakamura T., Sato T., Nakane Y., Nakashima H., Sakamoto Y., Taniguchi S., Nakao N., Tamii A., Shima T., and Hatanaka K.

Subjects

Physics, QC1-999

Abstract

Radiation monitoring at high energy proton accelerators poses a considerable challenge due to the complexity of the encountered stray radiation fields. These environments comprise a wide variety of different particle types and span from fractions of electron-volts up to several terra electron-volts. As a consequence the use of Monte Carlo simulation programs like FLUKA is indispensable to obtain appropriate field-specific calibration factors. At many locations of the LHC a large contribution to the particle fluence is expected to originate from high-energy neutrons and thus, benchmark experiments with mono-energetic neutron beams are of high importance to verify the aforementioned detector response calculations. This paper summarizes the results of a series of benchmark experiments with quasi mono-energetic neutrons of 100, 140, 200, 250 and 392 MeV that have been carried out at RCNP - Osaka University, during several campaigns between 2006 and 2014.

Published

2017

2. A Shielding Concept for the MedAustron Facility

Author

Jägerhofer L., Feldbaumer E., Roesler S., Theis C., and Vincke H.

Subjects

EBG MedAustron GmbH, Shielding Calculations, Hadron Therapy, FLUKA, Physics, QC1-999

Abstract

MedAustron is a synchrotron based accelerator facility for cancer therapy and research in Wiener Neustadt, 50 km south of Vienna. The facility will provide protons up to kinetic energies of 250 MeV and carbon ions up to 400 MeV/n for ion beam therapy. Additionally, protons up to 800 MeV kinetic energy will be used in a dedicated room for non-clinical research. In order to obtain a shielding concept for this facility a detailed geometry of the accelerator facility was implemented into the Monte-Carlo code FLUKA and shielding simulations were performed. In the course of these simulations the contributions of different particle types to the mixed fields around the accelerator and behind shielding were analysed. In an iterative process with the architect the final design of the shielding concept was developed until it was capable of reducing the effect of secondary radiation on humans and the environment below Austrian legal limits.

Published

2017

3. Characterization of the PTW 34031 ionization chamber (PMI) at RCNP with high energy neutrons ranging from 100 -- 392 MeV.

Author

Carbonez, P., Feldbaumer, E., Forkel-Wirth, D., Jaegerhofer, L., Pangallo, M., Perrin, D., Urscheler, C., Roesler, S., Vincke, H., Theis, C., Widorski, M., Tamii, A., Shima, T., Hatanaka, K., Iwamoto, Y., Satoh, D., Sato, T., Nakane, Y., Nakashima, H., and Sakamoto, Y.

Subjects

IONIZATION chambers, NEUTRONS, MONOENERGETIC radiation

Abstract

Radiation monitoring at high energy proton accelerators poses a considerable challenge due to the complexity of the encountered stray radiation fields. These environments comprise a wide variety of different particle types and span from fractions of electron-volts up to several terra electron-volts. As a consequence the use of Monte Carlo simulation programs like FLUKA is indispensable to obtain appropriate field-specific calibration factors. At many locations of the LHC a large contribution to the particle fluence is expected to originate from high-energy neutrons and thus, benchmark experiments with mono-energetic neutron beams are of high importance to verify the aforementioned detector response calculations. This paper summarizes the results of a series of benchmark experiments with quasi mono-energetic neutrons of 100, 140, 200, 250 and 392 MeV that have been carried out at RCNP - Osaka University, during several campaigns between 2006 and 2014. [ABSTRACT FROM AUTHOR]

Published

2017

4. MACHINE and RADIATION PROTECTION CHALLENGES of HIGH ENERGY/INTENSITY ACCELERATORS: The ROLE of MONTE CARLO CALCULATIONS.

Author

Besana, M. I., Bahamonde Castro, C., Cerutti, F., Damjanovic, S., Esposito, L. S., Ferrari, A., Froeschl, R., Iliopoulou, E., Lechner, A., Mereghetti, A., Roesler, S., Skordis, E., Tsinganis, A., Vlachoudis, V., and Vollaire, J.

Subjects

MONTE Carlo method, RADIATION, PARTICLE beams, PARTICLE accelerators, SYNCHROTRON radiation

Abstract

A conference paper on the role of monte carlo calculation in machine and radiation protection of high energy accelerators is discussed. It outlines beam losses, beam machine interaction and machine cases. The paper also examines particle interaction with accelerator material. Topics include beam loss monitor system, luminosity losses and synchrontron radiation.

Published

2017

5. Characterization of the PTW 34031 ionization chamber (PMI) at RCNP with high energy neutrons ranging from 100 – 392 MeV.

Author

Nakao, N., Theis, C., Carbonez, P., Feldbaumer, E., Forkel-Wirth, D., Jaegerhofer, L., Pangallo, M., Perrin, D., Urscheler, C., Roesler, S., Vincke, H., Widorski, M., Tamii, A., Shima, T., Hatanaka, K., Iwamoto, Y., Satoh, D., Sato, T., Nakane, Y., and Nakashima, H.

Subjects

RADIATION measurements, PROTON accelerators, RADIATION, ELECTRONS, MONTE Carlo method

Abstract

Radiation monitoring at high energy proton accelerators poses a considerable challenge due to the complexity of the encountered stray radiation fields. These environments comprise a wide variety of different particle types and span from fractions of electron-volts up to several terra electron-volts. As a consequence the use of Monte Carlo simulation programs like FLUKA is indispensable to obtain appropriate field-specific calibration factors. At many locations of the LHC a large contribution to the particle fluence is expected to originate from high-energy neutrons and thus, benchmark experiments with mono-energetic neutron beams are of high importance to verify the aforementioned detector response calculations. This paper summarizes the results of a series of benchmark experiments with quasi mono-energetic neutrons of 100, 140, 200, 250 and 392 MeV that have been carried out at RCNP - Osaka University, during several campaigns between 2006 and 2014. [ABSTRACT FROM AUTHOR]

Published

2017