M. Katagiri scite author profile

M. Katagiri

5Publications

14Citation Statements Received

30Citation Statements Given

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Affiliations

Hokkaido University of Science, Hokkaido University, Daido University

Publications

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Effective Doses and Organ Doses per Unit Fluence Calculated for Monoenergetic 0.1 MeV to 100 MeV Electrons by the MIRD-5 Phantom

Katagiri¹,

Hikoji²,

Kitaichi³

et al. 2000

Radiation Protection Dosimetry

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To determine quantities for radiation protection against high-energy electrons, such as those from LINAC, the organ dose equivalents and equivalent doses for the human body were calculated using EGS-4 Monte Carlo simulation code and an MIRD-5 mathematical human phantom. Conversion factors for the incident fluence to the organ dose equivalent, to the effective dose and to the effective dose equivalent for monoenergetic electrons were obtained for AP and PA geometrical irradiation conditions at incident energies from 0.1 to 100MeV. The agreement between the results of the present study of effective doses and those of other studies was acceptable within the statistical uncertainties. At energies lower than 10MeV, the skin sensitive layer was taken into account in some computations. It was found that the effective doses depend on the incident electron energy, beam size, and exposure position of the body.

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Pulse radiolysis studies of the reactions of bromine atoms and dimethyl sulfoxide–bromine atom complexes with alcohols

Sumiyoshi

Fujiyoshi

Katagiri

et al. 2007

Radiation Physics and Chemistry

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Effective Doses and Organ Doses in the MIRD-5 Phantom Exposed to Monoenergetic 0.1 MeV to 200 MeV Electrons in the LAT Direction

Katagiri

Hikoji²,

Kitaichi³

et al. 2001

Radiation Protection Dosimetry

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Organ doses and effective doses were calculated using the EGS-4 Monte Carlo simulation code and a MIRD-5 mathematical human phantom placed in a vacuum. For broad right and left lateral beams of monoenergetic (0.1-200 MeV) electrons, conversion coefficients from the incident fluence to organ dose, to effective dose, and to effective dose equivalent were obtained. There were no clear differences between the conversion coefficients in the case of left-lateral (LLAT) and right-lateral (RLAT) irradiation. Therefore, when investigating lateral geometries for electron exposure, it is not necessary to evaluate both directions independently. In general, conversion coefficients for lateral irradiation (LAT) were smaller than those for AP and PA. The difference between the AP and PA conversion coefficients and LAT became smaller with increasing incident energy; at 200 MeV the conversion coefficients were almost independent of the irradiation geometry. The agreement between the results of the present study and those of other studies was acceptable within the statistical uncertainties.

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Fluence to effective dose conversion coefficients calculated for monoenergetic electrons up to 200 MeV in partial exposure geometries

Kitaichi

Katagiri²,

Hikoji³

et al. 2004

Radiation Protection Dosimetry

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Organ doses and effective doses were calculated for monoenergetic electrons from 0.1 to 200 MeV using the EGS4 Monte Carlo simulation code and the MIRD-5 human phantom in various non-uniform exposure geometries: anterior-posterior (AP) and posterior-anterior (PA). Below 1 MeV, the skin is the main contributor to the effective dose conversion coefficients for each exposure geometry; however, above 1 MeV the calculations showed that the effective doses of partial exposures depended on the incident electron energy, the place and the size of the exposure on the body.

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Real-Time Dosimetry Method Using an Imaging Plate

Sakasai¹,

Katagiri²,

Kishimoto³

et al. 2001

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The real-time dosimetry method using an imaging plate has been studied. A small, remote radiation sensor using commercially available imaging plates has been developed for the purpose. The sensor adopts wavelength shift fibers for signal transmission and side-glow fibers for illumination of laser on the imaging plates. The developed sensor will be useful for various purposes such as local dose monitoring in reactors and beam loss monitoring in accelerator facilities.

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M. Katagiri

Effective Doses and Organ Doses per Unit Fluence Calculated for Monoenergetic 0.1 MeV to 100 MeV Electrons by the MIRD-5 Phantom

Pulse radiolysis studies of the reactions of bromine atoms and dimethyl sulfoxide–bromine atom complexes with alcohols

Effective Doses and Organ Doses in the MIRD-5 Phantom Exposed to Monoenergetic 0.1 MeV to 200 MeV Electrons in the LAT Direction

Fluence to effective dose conversion coefficients calculated for monoenergetic electrons up to 200 MeV in partial exposure geometries

Real-Time Dosimetry Method Using an Imaging Plate

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