@article{oai:nifs-repository.repo.nii.ac.jp:00000513,
 author = {MORITA,  Shigeru and DONG,  Chunfeng and GOTO,  Motoshi and KOBAYASHI,  Masahiro and MUTO,  Sadatsugu and YAMAZAKI,  Kozo and YOKOYAMA,  Masayuki and ZHOU,  Hangyu and AKIYAMA,  Tsuyoshi and ASHIKAWA,  Naoko and CU,  Zhengying and FUJII,  Keisuke and GAO,  Xiang and HASUO,  Masahiro and IDA,  Katsumi and IKEDA,  Katsunori and IWAMAE,  Atsushi and KANEKO,  Osamu and MASUZAKI,  Suguru and MIYAZAWA,  Junichi and MORISAKI,  Tomohiro and NAGAOKA,  Kenichi and NARIHARA,  Kazumichi and OHDACHI,  Satoshi and OSAKABE,  Masaki and SAKAKIBARA,  Satoru and SAKAMOTO,  Ryuichi and SHOJI,  Mamoru and TAKEIRI,  Yasuhiko and TANAKA,  Kenji and TOI,  Kazuo and TOKITANI,  Masayuki and TOKUZAWA,  Tokihiko and TSUMORI,  Katsuyoshi and WATANABE,  Kiyomasa and YAMADA,  Hiroshi and YAMADA,  Ichihiro and YANAGIBAYASHI,  Jun and YOSHINUMA,  Mikiro and KOMORI,  Akio and LHD, experiment group},
 journal = {Plasma and Fusion Research},
 month = {Jan},
 note = {A variety of density profiles observed in the Large Helical Device (LHD) have suggested an interesting core impurity transport. The edge impurity transport in the ergodic layer formed by stochastic magnetic field lines with long connection length (10-2000 m) can also exhibit interesting phenomena in the competition of perpendicular and parallel transport. The LHD discharge is highly robust against impurity buildup, and operation is possible essentially up to the global power balance limit because current-driven instability does not principally exist. The LHD plasma has therefore provided information on many interesting physics issues closely related to impurities. Recent results of impurity-related physics experiments in the LHD are briefly reviewed. The specific contents presented here are (1) core impurity behavior with perpendicular transport, (2) edge impurity behavior with parallel transport, (3) high-Z discharges with high ion temperature, (4) impurity pellet injection with improved plasma performance, (5) impurity pellet ablation in the presence of energetic ions with high heat flux and (6) observation of magnetic dipole forbidden transitions for high-Z elements. A result from the Compact Helical System (CHS) is used only in the impurity pellet ablation study, because detailed data have not yet been obtained from the LHD. Finally, the results are summarized and future directions in these topics are noted.},
 title = {Progress in Impurity-Related Physics Experiments in LHD},
 volume = {Vol.5},
 year = {2010}
}