Physics Analysis of the FIRE Experiment | Zendy

S.C. Jardin | Zendy; C. Kessel | Zendy; Douglas B. Meade | Zendy; J. Breslau | Zendy; G. Y. Fu | Zendy; Н. Н. Гореленков | Zendy; Janardhan Manickam | Zendy; W. Park | Zendy; H. R. Strauss | Zendy

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Physics Analysis of the FIRE Experiment

Author(s) -

S.C. Jardin,

C. Kessel,

Douglas B. Meade,

J. Breslau,

G. Y. Fu,

Н. Н. Гореленков,

Janardhan Manickam,

W. Park,

H. R. Strauss

Publication year - 2002

Publication title -

osti oai (u.s. department of energy office of scientific and technical information)

Language(s) - English

Resource type - Reports

DOI - 10.2172/798204

Subject(s) - pedestal , sawtooth wave , physics , core model , nuclear engineering , enhanced data rates for gsm evolution , core (optical fiber) , range (aeronautics) , power (physics) , code (set theory) , statistical physics , mechanics , simulation , computational physics , aerospace engineering , mechanical engineering , computer science , engineering , optics , thermodynamics , mathematical analysis , telecommunications , mathematics , set (abstract data type) , programming language , computer vision

An integrated model of a complete discharge in the FIRE experiment has been developed based on the TSC simulation code. The complete simulation model includes a choice of several models for core transport, combined with an edge pedestal model and the Porcelli sawtooth model. Burn control is provided by feedback on the auxiliary heating power. We find that with the GLF23 and MMM95 transport models, Q >10 operation should be possible for H-mode pedestal temperatures in the range of 4-5 keV

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