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The isotope effect on impurities and bulk ion particle transport in the Large Helical Device

Authors :
Gen Motojima
Hiroto Takahashi
Motoki Nakata
Masayuki Yokoyama
K. Yamazaki
T. Oishi
Ryuichi Sakamoto
M. Emoto
Ryosuke Seki
Naoki Tamura
Suguru Masuzaki
R. Mackenbach
Kenichi Nagaoka
Izumi Murakami
Kiyofumi Mukai
Masaki Osakabe
Mikirou Yoshinuma
Junwei Chen
Chihiro Suzuki
S. Morita
Katsumi Ida
Haruhisa Nakano
Sadayoshi Murakami
Tomohiro Morisaki
Shuji Kamio
Masanori Nunami
Y. Fujiwara
Motoshi Goto
T. Kobayashi
K. Fuji
Hiroshi Yamada
Science and Technology of Nuclear Fusion
Turbulence in Fusion Plasmas
Source :
Nuclear Fusion, 59(5):056029. Institute of Physics, K. Ida et al 2019 Nucl. Fusion 59 056029, Nuclear Fusion
Publication Year :
2019

Abstract

The isotope effect on impurities and bulk ion particle transport is investigated by using the deuterium, hydrogen, and isotope mixture plasma in the Large Helical Device (LHD). A clear isotope effect is observed in the impurity transport but not the bulk ion transport. The isotope effects on impurity transport and ion heat transport are observed as a primary and a secondary effect, respectively, in the plasma with an internal transport barrier (ITB). In the LHD, an ion ITB is always transient because the impurity hole triggered by the increase of ion temperature gradient causes the enhancement of ion heat transport and gradually terminates the ion ITB. The formation of an impurity hole becomes slower in the deuterium (D) plasma than the hydrogen (H) plasma. This primary isotope effect on impurity transport contributes the longer sustainment of the ion ITB state because the low ion thermal diffusivity can be sustained as long as the normalized carbon impurity gradient R/L n,c, where L c =-(∇n c/n c) -1 is above the critical value (∼-5). Therefore, the longer sustainment of the ITB state in the deuterium plasma is considered to be a secondary isotope effect due to the mitigation of the impurity hole. The radial profile of H and D ion density is measured using bulk charge exchange spectroscopy inside the isotope mixture plasma. The decay time of H ion density after the H-pellet injection and the decay time of D ion density after D-pellet injection are almost identical, which demonstrates that there is no significant isotope effect on ion particle transport.

Details

Language :
English
ISSN :
17414326, 10090630, 07413335, and 00295515
Database :
OpenAIRE
Journal :
Nuclear Fusion, 59(5):056029. Institute of Physics, K. Ida et al 2019 Nucl. Fusion 59 056029, Nuclear Fusion
Accession number :
edsair.doi.dedup.....f540d2fbac9e032c9b0d832764b32b11
Full Text :
https://doi.org/10.1088/1741-4326/ab0e41