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Electron Energy Confinement for HHFW Heating and Current Drive Phasing on NSTX
Author(s) -
J. C. Hosea,
S. Bernabei,
T. M. Biewer,
B. LeBlanc,
C. K. Phillips,
J. R. Wilson,
D. Stutman,
Peter Ryan,
D. W. Swain
Publication year - 2005
Language(s) - English
Resource type - Reports
DOI - 10.2172/839537
Subject(s) - sawtooth wave , electron , atomic physics , excitation , plasma , electron temperature , wavelength , laser , current (fluid) , physics , optics , quantum mechanics , computer science , computer vision , thermodynamics
Thomson scattering laser pulses are synchronized relative to modulated HHFW power to permit evaluation of the electron energy confinement time during and following HHFW pulses for both heating and current drive antenna phasing. Profile changes resulting from instabilities require that the total electron stored energy, evaluated by integrating the midplane electron pressure P(sub)e(R) over the magnetic surfaces prescribed by EFIT analysis, be used to derive the electron energy confinement time. Core confinement is reduced during a sawtooth instability but, although the electron energy is distributed outward by the sawtooth, the bulk electron energy confinement time is essentially unaffected. The radial deposition of energy into the electrons is noticeably more peaked for current drive phasing (longer wavelength excitation) relative to that for heating phasing (shorter wavelength excitation) as is expected theoretically. However, the power delivered to the core plasma is reduced consider ably for the current drive phasing, indicating that surface/peripheral damping processes play a more important role for this case

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