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Kinase, Sakae; Takagi, Shunji*; Noguchi, Hiroshi; Saito, Kimiaki
Radiation Protection Dosimetry, 125(1-4), p.189 - 193, 2007/07
Times Cited Count:16 Percentile:71.98(Environmental Sciences)In the Japan Atomic Energy Research Institute (JAERI), a calculation code -UCWBC code- for whole-body counter calibrations using voxel phantoms has been developed as an EGS4 Monte Carlo user code. To validate the UCWBC code for calibrating whole-body counters in JAERI, response functions and counting efficiencies of a p-type high-purity Ge semiconductor detector used for the whole-body counter were evaluated for a water-filled block-shape phantom by the UCWBC code and were measured by experiments. Furthermore, counting efficiencies of the Ge semiconductor detector for the male and female voxel phantoms developed in JAERI were evaluated in the photon energy range 60-1836 keV by the UCWBC code in order to examine the differences between the counting efficiencies for voxel phantoms. In conclusion, it was found that the response functions and counting efficiencies of the Ge semiconductor detector by the UCWBC code for the water-filled block-shape phantom are in good agreement with measured data. The UCWBC code was validated by the comparisons.
Kinase, Sakae; Noguchi, Hiroshi; Nakamura, Takashi*
Radiation Protection Dosimetry, 105(1-4), p.467 - 472, 2003/09
Times Cited Count:4 Percentile:31.59(Environmental Sciences)To calibrate a whole-body counter, it is necessary to find a determination method for peak efficiencies of detectors that the whole-body counter has. For the purpose, peak efficiencies of a Ge semi-conductor detector for point sources and volume sources were evaluated in the photon energy range of 60-1,836 keV by Monte Carlo simulation and experiment. It was found that the calculated peak efficiency curves as a function of energy without modeling the actual sensitive region of the detector are similar in shape to those measured. The calculated peak efficiencies of the detector that has an apparent dead layer (1mm) were also found to agree with the experimental values. Consequently, the simulation method for peak efficiencies was validated. In addition, an optimum design for a whole-body counter with Ge semi-conductor detectors was examined by simulation. This simulation enables to provide a method to determine an optimum arrangement of detectors in a whole-body counter offering a uniform response to various Cs-137 distributions in a human body.
Kinase, Sakae
JAERI-Research 2003-011, 104 Pages, 2003/05
In the present study, a calibration technique for in vivo counting application using Monte Carlo simulation was developed. The advantage of the technique is that counting efficiency can be obtained for various shapes, sizes that is very difficult to change for phantoms. The method for the determination of counting efficiency curves as a function of energy was developed using the present technique and a physiques correction equation was derived from the relationship between parameters of correction factor and counting efficiencies of the JAERI whole-body counter. The uncertainties in body burdens of Cs-137 estimated with the JAERI whole-body counter were also investigated using the Monte Carlo simulation and measurements. Furthermore, the evaluation method of the peak efficiencies of a Ge semi-conductor detector was developed by the Monte Carlo simulation for optimum arrangement of Ge semi-conductor detectors for designing a precision whole-body counter.
Kinase, Sakae
Medical Physics, 30(5), P. 994, 2003/05
A calibration technique for in vivo counting application using Monte Carlo simulation was developed. To validate the calibration technique by calculations, the response functions and counting efficiencies of a whole-body counter installed in JAERI were evaluated using the simulation and measurements. Consequently, the calculations are in good agreement with the measurements. The uncertainties in body burdens of 137Cs estimated with the whole-body counter were also investigated using the Monte Carlo simulation and measurements. It was found that the uncertainties of body burdens estimated with the whole-body counter are strongly dependent on various sources of uncertainty such as radioactivity distribution within the body and counting statistics.
Yamamoto, Kazuyoshi; Kishi, Toshiaki; Hori, Naohiko; Kumada, Hiroaki; Torii, Yoshiya; Horiguchi, Yoji
JAERI-Tech 2001-016, 34 Pages, 2001/03
no abstracts in English
Konno, Chikara; Maekawa, Fujio; Kasugai, Yoshimi; Uno, Yoshitomo; Kaneko, Junichi; Nishitani, Takeo; Wada, Masayuki*; Ikeda, Yujiro; Takeuchi, Hiroshi
Nuclear Fusion, 41(3), p.333 - 337, 2001/03
Times Cited Count:3 Percentile:10.95(Physics, Fluids & Plasmas)no abstracts in English
Maekawa, Fujio; Wada, Masayuki*; Konno, Chikara; Kasugai, Yoshimi; Ikeda, Yujiro
Fusion Engineering and Design, 51-52(Part.B), p.809 - 814, 2000/11
Times Cited Count:6 Percentile:42.55(Nuclear Science & Technology)no abstracts in English
Maekawa, Fujio; Wada, Masayuki*; Ikeda, Yujiro
Nuclear Instruments and Methods in Physics Research A, 450(2-3), p.467 - 478, 2000/08
Times Cited Count:6 Percentile:44.13(Instruments & Instrumentation)no abstracts in English
Mori, Takamasa; Okumura, Keisuke; Nagaya, Yasunobu; Nakakawa, Masayuki
Mathematics and Computation, Reactor Physics and Environmental Analysis in Nuclear Applications, 2, p.987 - 996, 1999/09
no abstracts in English
Ito, Hitoshi
Hoshasen To Sangyo, (82), p.54 - 56, 1999/06
no abstracts in English
Maekawa, Fujio; Ikeda, Yujiro
Proc. of Int. Conf. on Nucl. Data for Science and Technol., 59, p.1201 - 1205, 1997/00
no abstracts in English
Nakakawa, Masayuki; Mori, Takamasa
Journal of Nuclear Science and Technology, 30(7), p.692 - 701, 1993/07
Times Cited Count:33 Percentile:92.41(Nuclear Science & Technology)no abstracts in English
Journal of Nuclear Science and Technology, 14(12), p.911 - 915, 1977/12
Times Cited Count:2no abstracts in English
; ; *; Kazuo.Yanagisita*
Health Physics, 9, p.529 - 535, 1963/00
no abstracts in English
Whole-body Counting, p.219 - 233, 1962/00
no abstracts in English
Murakami, Yohei*; Mitsuyasu, Takeshi*; Miwa, Junichi*; Hino, Tetsushi*; Suyama, Kenya; Nagaya, Yasunobu
no journal, ,
A Monte Carlo code system has been developed to design an innovative water-cooled reactor, Resource-renewable Boiling Water Reactor (RBWR), which enables to burn transuranium elements (TRUs) efficiently. The system can perform multiphysics calculations of whole-core Monte Carlo neutronics, thermal-hydraulics and burnup; thus uncertainty induced by group-constant generation can be excluded. It has been confirmed that the pseudo material construct method can reduce memory requirement significantly and thus the reactor core design with whole core Monte Carlo calculations can be performed even with current computational resource.
Miwa, Junichi*; Hino, Tetsushi*; Mitsuyasu, Takeshi*; Nagaya, Yasunobu
no journal, ,
We performed whole-core Monte Carlo calculations for core design verification of an innovative BWR concept, resource-renewable boiling water reactor (RBWR). The calculations include a coupled neutronics/thermal-hydraulics calculation with a continuous-energy Monte Carlo code MVP and an inhouse thermal-hydraulics code, and a burnup calculation with the MVP-BURN code. Such calculations for the RBWR is challenging because it requires a large memory size and a large amount of calculation time. The typical memory size required for the RBWR calculations was an order of 10 GBytes per CPU in parallel computing using a desktop PC cluster. The total calculation time for calculating the characteristics of the equilibrium core of RBWR with the whole-core Monte Carlo burnup calculation using the desktop PC cluster was about 20 days. We demonstrated that the design calculations for the RBWR were possible with such a desktop PC cluster.