@article{oai:nifs-repository.repo.nii.ac.jp:00000592,
 author = {TAKEIRI,  Yasuhiko and KOMORI,  Akio and YAMADA,  Hiroshi and KAWAHATA,  Kazuo and MUTOH,  Takashi and OHYABU,  Nobuyoshi and KANEKO,  Osamu and IMAGAWA,  Sinsaku and NAGAYAMA,  Yoshio and WATANABE,  Kiyomasa and SHIMOZUMA,  Takashi and IDA,  Katsumi and SAKAMOTO,  Ryuichi and KOBAYASHI,  Masahiro and SAGARA,  Akio and NAGAOKA,  Kenichi and YOSHINUMA,  Mikiro and SAKAKIBARA,  Satoru and SUZUKI,  Yasuhiro and YOKOYAMA,  Masayuki and SUDO,  Shigeru and MOTOJIMA,  Osamu and the, LHD Experimental Group},
 journal = {Plasma and Fusion Research},
 month = {Jan},
 note = {Recent progress in plasma performance and the understanding of the related physics in the Large Helical Device is overviewed. The volume-averaged beta value is increased with an increase in the neutral beam injection (NBI) heating power, and it reached 5.0% of the reactor-relevant value. In high-β plasmas, the plasma aspect ratio should be controlled so that the Shafranov shift would be reduced, mainly to suppress transport degradation and the deterioration of the NBI heating efficiency. The operational regime of a high-density plasma with an internal diffusion barrier (IDB) has been extended, and the IDB, which was originally found using the local island divertor, has been realized in the helical divertor configuration. The central density was recorded as high as 1 × 1021 m-3, and the central pressure reached 130 kPa. Based on these high-density plasmas with the IDB, a new ignition scenario has been proposed. This should be a scenario specific to the helical fusion reactor, in which the helical ripple transport would be mitigated. A low-energy positive-NBI system was newly installed for an increase in the direct ion heating power. As a result, the ion temperature (Ti) exceeded 5.2 keV at a density of 1.2 × 1019 m-3 in a hydrogen plasma. Transport analysis shows improvement of ion transport, and the Ti-increase tends to be accompanied by a large toroidal rotation velocity of the order of 50 km/s in the core region. The plasma properties in the extended operational regime are discussed from the perspective of a steady-state helical fusion reactor.},
 title = {Stability and Confinement Studies of High-Performance NBI Plasmas in the Large Helical Device Toward a Steady-State Helical Fusion Reactor},
 volume = {Vol.3},
 year = {2008}
}