Your search keyword '"Miyuki Yajima"' showing total 10 results

1. Penetration of deuterium into neutron-irradiated tungsten under plasma exposure

Author

Yasuhisa Oya, Yuji Hatano, Vladimir Kh. Alimov, Noriyasu Ohno, Takeshi Toyama, T. Kuwabara, Miyuki Yajima, Alexander V. Spitsyn, and Thomas Schwarz-Selinger

Subjects

Materials science, Plasma exposure, chemistry, Deuterium, Radiochemistry, chemistry.chemical_element, Neutron, Penetration (firestop), Irradiation, Tungsten, Condensed Matter Physics, Mathematical Physics, Atomic and Molecular Physics, and Optics

Published

2021

2. Fuzzy nanostructure growth on precious metals by He plasma irradiation

Author

Tsuyoshi Akiyama, Noriyasu Ohno, Masayuki Tokitani, Naoaki Yoshida, Miyuki Yajima, Hirohiko Tanaka, Y. Tomita, Shin Kajita, Takashi Yagi, and Tomohiro Nojima

Subjects

inorganic chemicals, Materials science, Plasma irradiation, Morphology (linguistics), Nanostructure, genetic structures, chemistry.chemical_element, 01 natural sciences, 010305 fluids & plasmas, Low energy, 0103 physical sciences, Physics::Atomic and Molecular Clusters, Materials Chemistry, Physics::Atomic Physics, Helium bubbles, Helium, 010302 applied physics, Surfaces and Interfaces, General Chemistry, respiratory system, Condensed Matter Physics, Surfaces, Coatings and Films, respiratory tract diseases, Chemical engineering, chemistry, Helium ions, Precious metals, sense organs, circulatory and respiratory physiology

Abstract

Growth of helium bubbles near the surface of metals leads to various morphology changes when sufficient helium ions are continuously implanted on the surface. In this study, low energy (< 100 eV) helium plasma irradiations to various noble metals were conducted, and consequent surface morphology changes were analyzed. It was found that fiberform nanostructures were formed by the helium plasma irradiation on rhodium and ruthenium thin films, which were deposited by magnetron sputtering, and on platinum and iridium wires. Growth of fiberform structures were not identified on gold, silver, and palladium samples exposed to helium plasmas even though the irradiations were conducted at various surface temperatures, though pinholes were observed on palladium surface. We discussed the relation between the morphology changes and material properties., ファイル公開：2020-04-25

Published

2018

3. Dynamics of Hydrogen Isotope Absorption and Emission of Neutron-Irradiated Tungsten

Author

T. Kuwabara, Miyuki Yajima, Takeshi Toyama, Noriyasu Ohno, Vladimir Kh. Alimov, and Yuji Hatano

Subjects

inorganic chemicals, Materials science, tungsten, Hydrogen isotope, technology, industry, and agriculture, Analytical chemistry, chemistry.chemical_element, Tungsten, Condensed Matter Physics, chemistry, Deuterium, Neutron, Irradiation, neutron irradiation, Absorption (electromagnetic radiation), Neutron irradiation, TDS, deuterium

Abstract

This overview presents recent results regarding hydrogen isotope absorption and emission dynamics in neutron-irradiated tungsten (W) using our recently developed Compact Diverter Plasma Simulator (CDPS), a linear plasma device in a radiation-controlled area. Neutron irradiation to 0.016 - 0.06 displacement per atom resulted in a significant increase in deuterium (D) retention due to trapping effects of radiation-induced defects. We analyzed the dependency of D retention on the D plasma fluence by exposing neutron-irradiated pure W to D plasma at 563 K over a range of D fluence values. The total retention was revealed to be proportional to the square root of D fluence, indicating that the implanted D atoms first occupy the defects caused by neutron-irradiation near the surface and then the defects located in deeper regions. We further investigated the effects of post-plasma annealing on D emission; neutron-irradiated pure W was exposed to D plasma at 573 K and was then annealed at the same temperature for 30 hours. Approximately 10% of the absorbed D was released by annealing, suggesting that a heat treatment of the plasma-facing component of a fusion reactor at moderately elevated temperatures could contribute to the removal of accumulated hydrogen isotopes. The experimental results obtained in this study were only available by investigating neutron-irradiated specimens with the CDPS system, which will be essential for future studies of material behavior and plasma-wall interactions in the fusion reactor environment.

Published

2020

4. Tritium Balance in Large Helical Device during and after the First Deuterium Plasma Experiment Campaign

Author

Masahiro Tanaka, Chie Iwata, Miyuki Yajima, Miki Nakada, Naoyuki Suzuki, Hiromi Kato, and Suguru Masuzaki

Subjects

inorganic chemicals, Materials science, deuterium plasma experiment, vacuum vessel ventilation, Nuclear engineering, organic chemicals, tritium balance, tritium release behavior, Condensed Matter Physics, Large Helical Device, tritium inventory, Deuterium plasma, Balance (accounting), polycyclic compounds, cardiovascular system, Tritium

Abstract

The Large Helical Device (LHD) started the deuterium plasma experiment on March 7, 2017. Approximately 6.4 GBq of tritium was produced in the first deuterium plasma experiment campaign and were utilized as tracers for the investigation of release behavior and the balance of tritium in the LHD vacuum vessel. To determine the tritium balance in LHD, the tritium release from the vacuum vessel was continually observed during the plasma experiment period and the vacuum vessel maintenance activities. The tritium exhaust rate was approximately 32.8% at the end of the plasma experiment. After the plasma experiment, the vacuum vessel was ventilated by room air for the maintenance activity and the tritium release from the in-vessel components was observed. The tritium release rate gradually decreased and became constant after four-month in spite of water vapor concentration. It is suggested that the tritium release mechanism from the vacuum vessel is a diffusion-limited process from the bulk. The tritium release amount during the maintenance activity for one year was approximately 5.0%. Considering the decrease of tritium decay for 1.5 years, tritium inventory in LHD was estimated to be approximately 3.66 GBq (57.2%) at the end of maintenance activity.

Published

2020

5. Microstructure and Retention in He-W Co-Deposition Layer

Author

Shin Kajita, Miyuki Yajima, Naoaki Yoshida, Hirohiko Tanaka, Noriyasu Ohno, D. Nagata, and Kosuke Asai

Subjects

plasma-material interactions, Materials science, Chemical engineering, Co-NAGDIS, He-W co-deposition, Co deposition, Condensed Matter Physics, Microstructure, Layer (electronics)

Abstract

A tungsten (W) deposition layer is formed while a sample is exposed to a helium (He) plasma at the surface temperature of 473 or 573 K. The formed He-W co-deposition layer was composed of fine grains, the size of which increased with the surface temperature. The samples with the co-deposition layer was exposed to a deuterium (D2) plasma, and the D retention was investigated using thermal desorption spectroscopy. It was found that the co-deposition layer has quite different D retention characteristics compared with bulk W.

Published

2020

6. Development of a Compact Divertor Plasma Simulator for Plasma-Wall Interaction Studies on Neutron-Irradiated Materials

Author

Ryo Nishimura, Yuji Hatano, Katuya Suzuki, Hiroaki Kurishita, T. Kuwabara, Akio Sagara, Takeshi Toyama, M. Takagi, Tatsuo Shikama, Miyuki Yajima, Naoaki Yoshida, and Noriyasu Ohno

Subjects

Materials science, Divertor, Nuclear engineering, neutron-irradiated material, Plasma, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Interaction studies, hydrogen isotope retention, Irradiated materials, divertor plasma simulator, 0103 physical sciences, Neutron, 010306 general physics, plasma-wall interaction

Abstract

We have developed a compact divertor plasma simulator (CDPS) that can produce steady-state deuterium and/or helium plasmas with densities above ∼ 1018 m−3 for Plasma-Wall Interaction (PWI) studies of neutron-irradiated materials. The maximum particle flux is about 1022 m−2s−1. The CDPS was installed and is being operated in the radiation-controlled area of the International Research Center for Nuclear Materials Science, Institute for Materials Research, Tohoku University. We are able to control sample temperature within uncertainty of 5 °C during plasma exposure by adjusting the cooling air flow rate to the sample holder. The CDPS has a sample-carrier system, which makes it possible to transfer a plasma-irradiated sample from the sample holder to an infrared heater for analysis using thermal desorption spectroscopy (TDS) without exposing it to the air. This avoids the oxidation of the sample and minimizes the time between the end of plasma exposure and TDS analysis. An ITER-like tungsten (W) sample (A.L.M.T. Corp.), which has been irradiated by neutrons to 0.06 dpa in a fission reactor, was exposed to a deuterium plasma in the CDPS. The experimental results clearly show that the total deuterium retention in the neutron-irradiated W sample increases significantly in comparison with a pristine W, as demonstrated by broadening of the TDS spectrum at high temperatures.

Published

2017

7. Extension of the operational regime of the LHD towards a deuterium experiment

Author

Takeshi Ido, Takeshi Higashiguchi, Noriyoshi Nakajima, M. Okamoto, Hideo Sugama, Hiroshi Yamada, Tsuyoshi Akiyama, Oliver Schmitz, Naoko Ashikawa, Shinsuke Satake, Masaharu Shiratani, Takashi Shimozuma, Kazuo Kawahata, M. Y. Tanaka, M. Ohno, Kazuo Toi, Shigeru Inagaki, Tetsuro Nagasaka, Shinji Hamaguchi, F. Castejón, Chihiro Suzuki, Arata Nishimura, J. Baldzuhn, M. Preynas, Masashi Kisaki, Hirohiko Tanaka, Y. Yamamoto, H. Miura, Takuya Saze, Y. Takemura, Yasunori Tanaka, Naofumi Akata, S. Morita, S. Sagara, Nobuaki Yoshida, Shinichiro Toda, Hisamichi Funaba, Osamu Yamagishi, Suguru Masuzaki, Ichihiro Yamada, Y. Takeuchi, Masaki Nishiura, Yutaka Matsumoto, José Luis Velasco, Kiyofumi Mukai, Yasuhiko Takeiri, Kazunori Koga, Motoshi Goto, Masanori Nunami, Arimichi Takayama, Chanho Moon, Ryuichi Sakamoto, Y. Hayashi, Ritoku Horiuchi, Hirotaka Chikaraishi, Seiji Ishiguro, Atsushi Ito, Yasuhiro Suzuki, Torsten Stange, R. Soga, Mieko Toida, Naoki Tamura, Kyosuke Shinohara, Hiroyuki A. Sakaue, Ryutaro Kanno, Hiroshi Kasahara, T. Kato, Gakushi Kawamura, Sadatsugu Takayama, K. Saito, Takeo Muroga, Seiya Nishimura, C. Skinner, Kensaku Kamiya, Sumio Kitajima, Katsuyoshi Tsumori, Tomohiro Morisaki, Izumi Murakami, Shin Kubo, K. Ito, Ryuhei Kumazawa, Shuji Kamio, Daisuke Nishijima, Masaki Osakabe, Juro Yagi, E. Bernard, Kazuya Takahata, Katsunori Ikeda, Osamu Mitarai, Motoki Nakata, Hiroyuki R. Takahashi, K. Nagaoka, Yuji Nakamura, Toseo Moritaka, Yasuhisa Oya, Hao Wang, N. Yamaguchi, Hayato Tsuchiya, Masayuki Yokoyama, Mizuki Sakamoto, Sadayoshi Murakami, Shinji Kobayashi, Akira Ejiri, Toshiyuki Mito, Suguru Takada, Masayuki Tokitani, I. A. Sharov, Mitsutaka Isobe, Sadatsugu Muto, Toru Ii Tsujimura, Daiji Kato, D. Gradic, Akihiro Ishizawa, Tsuguhiro Watanabe, R. Ishizaki, K.Y. Watanabe, C. Hidalgo, Shinsaku Imagawa, Keisuke Fujii, Ryohei Makino, Tokihiko Tokuzawa, Takashi Mutoh, Tetsuhiro Obana, Byron J. Peterson, M. Emoto, Hideya Nakanishi, Haruhisa Nakano, J.H. Lee, Sadao Masamune, Shinji Yoshimura, Yasushi Todo, Satoru Sakakibara, Teruya Tanaka, Mamoru Shoji, Katsumi Ida, Kenji Tanaka, Miyuki Yajima, T. Oishi, Shunsuke Usami, H. Noto, Akira Kohyama, Takuya Goto, Akio Sanpei, Yoshiro Narushima, Ryosuke Seki, Yasuo Yoshimura, A. Iwamoto, D. López-Bruna, Ryo Yasuhara, Yuji Nobuta, T. Kobayashi, Hiroki Hasegawa, Mikiro Yoshinuma, M. Sato, Naomichi Ezumi, K. Nishimura, Makoto I. Kobayashi, Hiroto Matsuura, Kazunobu Nagasaki, W.H. Ko, Yoshio Nagayama, Joon-Wook Ahn, E. Yatsuka, Yoshiki Hirooka, Naoki Mizuguchi, Nagato Yanagi, Tomo-Hiko Watanabe, Kunihiro Ogawa, Akihiro Shimizu, Osamu Kaneko, Katsuji Ichiguchi, Hitoshi Tamura, Gen Motojima, Tetsuo Seki, Takeo Nishitani, T. Bando, Y. Gunsu, Hiroaki Ohtani, Satoshi Ohdachi, J. Miyazawa, Hiroe Igami, Todd Evans, Yoshimitsu Hishinuma, Y. Ito, Noriyasu Ohno, and T. Ozaki

Subjects

Nuclear and High Energy Physics, Materials science, stellarator/heliotron, Extension (predicate logic), Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Large Helical Device, impurity transport, Deuterium, Physics::Plasma Physics, 0103 physical sciences, internal transport barrier, Atomic physics, 010306 general physics, Spectroscopy, high beta plasma

Abstract

As the finalization of a hydrogen experiment towards the deuterium phase, the exploration of the best performance of hydrogen plasma was intensively performed in the large helical device. High ion and electron temperatures, Ti and Te, of more than 6 keV were simultaneously achieved by superimposing high-power electron cyclotron resonance heating onneutral beam injection (NBI) heated plasma. Although flattening of the ion temperature profile in the core region was observed during the discharges, one could avoid degradation by increasing the electron density. Another key parameter to present plasma performance is an averaged beta value $\left\langle \beta \right\rangle $ . The high $\left\langle \beta \right\rangle $ regime around 4% was extended to an order of magnitude lower than the earlier collisional regime. Impurity behaviour in hydrogen discharges with NBI heating was also classified with a wide range of edge plasma parameters. The existence of a no impurity accumulation regime, where the high performance plasma is maintained with high power heating >10 MW, was identified. Wide parameter scan experiments suggest that the toroidal rotation and the turbulence are the candidates for expelling impurities from the core region.

Published

2017

8. In Situ TEM Observation of Helium Bubbles Collapsing on Nanostructured Tungsten during Annealing

Author

Naoaki Yoshida, Noriyasu Ohno, Miyuki Yajima, and Shin Kajita

Subjects

010302 applied physics, In situ, Materials science, helium bubble, tungsten, Annealing (metallurgy), fiberform nanostructure, chemistry.chemical_element, Tungsten, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, chemistry, Transmission electron microscopy, transmission electron microscopy, 0103 physical sciences, annealing, Composite material, Helium

Abstract

A fiberform nanostructured layer is formed on a tungsten (W) surface using helium (He) plasma irradiation. The behavior of the nanostructures and He bubbles were observed during annealing via in situ transmission electron microscopy. Notable changes in the nanostructures occurred at 1223 K. A collapse of the nanostructures was observed along with a collapse of the He bubbles during annealing.

Published

2016

9. Morphology and Optical Property Changes of Nanostructured Tungsten in LHD

Author

Masayuki Tokitani, Noriyasu Ohno, Shin Kajita, Naoaki Yoshida, Miyuki Yajima, and Tsuyoshi Akiyama

Subjects

Materials science, Morphology (linguistics), large helical device (LHD), Optical property, chemistry.chemical_element, Tungsten, Condensed Matter Physics, deposition, Chemical engineering, chemistry, Sputtering, nanostructured tungsten, sputtering, Deposition (chemistry)

Abstract

Nanostructured tungsten formed by the exposure to helium plasma in a linear plasma device was installed in the large helical device (LHD). After the exposure in a series of experiments in the 2012 fiscal year campaign in LHD, the samples were analyzed by scanning electron microscope (SEM), transmission electron microscope (TEM), and energy dispersion x-ray spectroscopy (EDX). It was found that part of the nanostructures was totally covered with carbon based material probably from divertor, while some other parts were eroded by sputtering. On the erosion dominant region, it was revealed that the head part of nanostructures was sputtered and the surface became rounded, but the nanostructures still remained near the surface. Optical reflectance of the material was measured, and it was found that the morphology changes increased the optical reflectivity up to ∼10% from typically less than 1%. The possibility and limitation of the nanostructured tungsten as a light absorber (viewing dump) are discussed.

Published

2015

10. Helium irradiation effects on the surface modification and recrystallization of tungsten

Author

M. Balden, A. Khan, M. Tokitani, Noriyasu Ohno, H. Greuner, Y. Tomita, K. Hunger, Shin Kajita, G. De Temmerman, Miyuki Yajima, D. Nagata, and Dogyun Hwangbo

Subjects

010302 applied physics, Materials science, Metallurgy, Recrystallization (metallurgy), chemistry.chemical_element, Tungsten, Condensed Matter Physics, 01 natural sciences, Atomic and Molecular Physics, and Optics, 010305 fluids & plasmas, chemistry, 0103 physical sciences, Surface modification, Helium irradiation, Mathematical Physics