Your search keyword '"Naoki Kiyono"' showing total 2 results

1. Applicability of composite materials for space radiation shielding of spacecraft

Author

Masayuki Naito, Toshiaki Endo, Yukio Uchihori, Tamon Kusumoto, Yusuke Hagiwara, Hisashi Kitamura, Hiromichi Akiyama, Masahiro Yamanaka, Wataru Nishimura, Shinobu Matsuo, Masamune Koike, Yasuhiro Takami, Ryo Mikoshiba, Hiroki Kusano, Satoshi Kodaira, Hiroaki Kodama, and Naoki Kiyono

Subjects

Materials science, Hydrogen, Ion beam, Health, Toxicology and Mutagenesis, Composite number, chemistry.chemical_element, Radiation Dosage, Ion, Radiation Protection, Stopping power (particle radiation), Shielding effect, Heavy Ions, Spacecraft, Composite material, Radiation, Ecology, business.industry, Astronomy and Astrophysics, Space Flight, Agricultural and Biological Sciences (miscellaneous), chemistry, Polyethylene, Electromagnetic shielding, business, Cosmic Radiation

Abstract

Energetic ion beam experiments with major space radiation elements, 1H, 4He, 16O, 28Si and 56Fe, have been conducted to investigate the radiation shielding properties of composite materials. These materials are expected to be used for parts and fixtures of space vehicles due to both their mechanical strength and their space radiation shielding capabilities. Low Z materials containing hydrogen are effective for shielding protons and heavy ions due to their high stopping power and large fragmentation cross section per unit mass. The stopping power of the composite materials used in this work is intermediate between that of aluminum and polyethylene, which are typical structural and shielding materials used in space. The total charge-changing cross sections per unit mass, σ UM , of the composite materials are 1.3–1.8 times larger than that of aluminum. By replacing conventional aluminum used for spacecraft with commercially available composite (carbon fiber / polyether ether ketone), it is expected that the shielding effect is increased by ∼17%. The utilization of composite materials will help mitigate the space radiation hazard on future deep space missions.

Published

2021

2. Investigation of shielding material properties for effective space radiation protection

Author

Toyoto Sato, Hiroki Kusano, Kenji Tobita, Masamune Koike, Yukio Uchihori, Hiroaki Kodama, Naoki Kiyono, Y. Someya, Yusuke Hagiwara, Hisashi Kitamura, Ryo Ogawara, Masahiro Yamanaka, Masayuki Naito, Ryo Mikoshiba, Shin Ichi Orimo, Toshiaki Endo, Yasuhiro Takami, Tamon Kusumoto, Shinobu Matsuo, and Satoshi Kodaira

Subjects

Materials science, 010504 meteorology & atmospheric sciences, Hydrogen, Health, Toxicology and Mutagenesis, Composite number, chemistry.chemical_element, Radiation Dosage, 01 natural sciences, chemistry.chemical_compound, Radiation Protection, Aluminium, 0103 physical sciences, Composite material, Spacecraft, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Radiation, Ecology, business.industry, Attenuation, Protective Devices, Astronomy and Astrophysics, Polyethylene, Agricultural and Biological Sciences (miscellaneous), chemistry, Electromagnetic shielding, Radiation protection, Material properties, business, Monte Carlo Method, Cosmic Radiation

Abstract

Geant4 Monte Carlo simulations were carried out to investigate the possible shielding materials of aluminum, polyethylene, hydrides, complex hydrides and composite materials for radiation protection in spacecraft by considering two physical parameters, stopping power and fragmentation cross section. The dose reduction with shielding materials was investigated for Fe ions with energies of 500 MeV/n, 1 GeV/n and 2 GeV/n which are around the peak of the GCR energy spectrum. Fe ions easily stop in materials such as polyethylene and hydrides as opposed to materials such as aluminum and complex hydrides including high Z metals with contain little or no hydrogen. Attenuation of the primary particles in the shielding and fragmentation into more lightly charged and therefore more penetrating secondary particles are competing factors: attenuation acts to reduce the dose behind shielding while fragmentation increases it. Among hydrogenous materials, 6Li10BH4 was one of the more effective shielding materials as a function of mass providing a 20% greater dose reduction compared to polyethylene. Composite materials such as carbon fiber reinforced plastic and SiC composite plastic offer 1.9 times the dose reduction compared to aluminum as well as high mechanical strength. Composite materials have been found to be promising for spacecraft shielding, where both mass and volume are constrained.

Published

2020