Confinement of high-density pellet-fueled discharges in TFTR
S L Milora; G L Schmidt; V Arunasalam; M G Bell; M Bitter; C E Bush; S K Combs; P C Efthimion; A C England; E Fredrickson; R J Goldston; B Grek; L Grisham; R J Hawyrluk; W Heidbrink; H W Hendel; K W Hill; D Johnson; L C Johnson; P LaMarche; R Little; D Mansfield; D C McCune; K McGuire; D M Meade; D Mueller; E B Nieschmidt; D K Owens; H Park; A T Ramsey; J F Schivell; S Sesnic; F Stauffner; B L Stratton; G Taylor; H H Towner; R M Wieland; J B Wilgen; M C Zarnstorff; S L Milora; Plasma Phys. Lab., Princeton Univ., NJ, USA; G L Schmidt; Plasma Phys. Lab., Princeton Univ., NJ, USA; V Arunasalam; Plasma Phys. Lab., Princeton Univ., NJ, USA; M G Bell; Plasma Phys. Lab., Princeton Univ., NJ, USA; M Bitter; Plasma Phys. Lab., Princeton Univ., NJ, USA; C E Bush; Plasma Phys. Lab., Princeton Univ., NJ, USA; S K Combs; Plasma Phys. Lab., Princeton Univ., NJ, USA; P C Efthimion; Plasma Phys. Lab., Princeton Univ., NJ, USA; A C England; Plasma Phys. Lab., Princeton Univ., NJ, USA; E Fredrickson; Plasma Phys. Lab., Princeton Univ., NJ, USA; R J Goldston; Plasma Phys. Lab., Princeton Univ., NJ, USA; B Grek; Plasma Phys. Lab., Princeton Univ., NJ, USA; L Grisham; Plasma Phys. Lab., Princeton Univ., NJ, USA; R J Hawyrluk; Plasma Phys. Lab., Princeton Univ., NJ, USA; W Heidbrink; Plasma Phys. Lab., Princeton Univ., NJ, USA; H W Hendel; Plasma Phys. Lab., Princeton Univ., NJ, USA; K W Hill; Plasma Phys. Lab., Princeton Univ., NJ, USA; D Johnson; Plasma Phys. Lab., Princeton Univ., NJ, USA; L C Johnson; Plasma Phys. Lab., Princeton Univ., NJ, USA; P LaMarche; Plasma Phys. Lab., Princeton Univ., NJ, USA; R Little; Plasma Phys. Lab., Princeton Univ., NJ, USA; D Mansfield; Plasma Phys. Lab., Princeton Univ., NJ, USA; D C McCune; Plasma Phys. Lab., Princeton Univ., NJ, USA; K McGuire; Plasma Phys. Lab., Princeton Univ., NJ, USA; D M Meade; Plasma Phys. Lab., Princeton Univ., NJ, USA; D Mueller; Plasma Phys. Lab., Princeton Univ., NJ, USA; E B Nieschmidt; Plasma Phys. Lab., Princeton Univ., NJ, USA; D K Owens; Plasma Phys. Lab., Princeton Univ., NJ, USA; H Park; Plasma Phys. Lab., Princeton Univ., NJ, USA; A T Ramsey; Plasma Phys. Lab., Princeton Univ., NJ, USA; J F Schivell; Plasma Phys. Lab., Princeton Univ., NJ, USA; S Sesnic; Plasma Phys. Lab., Princeton Univ., NJ, USA; F Stauffner; Plasma Phys. Lab., Princeton Univ., NJ, USA; B L Stratton; Plasma Phys. Lab., Princeton Univ., NJ, USA; G Taylor; Plasma Phys. Lab., Princeton Univ., NJ, USA; H H Towner; Plasma Phys. Lab., Princeton Univ., NJ, USA; R M Wieland; Plasma Phys. Lab., Princeton Univ., NJ, USA; J B Wilgen; Plasma Phys. Lab., Princeton Univ., NJ, USA; M C Zarnstorff; Plasma Phys. Lab., Princeton Univ., NJ, USA
Журнал:
Plasma Physics and Controlled Fusion
Дата:
1986-09-01
Аннотация:
TFTR pellet injection results reported by Schmidt (1985) have been extended to higher density and n tau in plasmas limited by a graphite inner-wall belt limiter. Increased pellet penetration and larger density increases were achieved by operation at reduced plasma current (1.6 MA) and minor and major radius (70 cm and 235 cm). Under these conditions, beam heating results have been extended to 7 MW.
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