Equilibrium and stability in a heliotron with anisotropic hot particle slowing-down distributionReport as inadecuate

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Published in: Physics of Plasmas (ISSN: 1070-664X), vol. 19, num. 10, p. 102503 Melville: American Institute of Physics, 2012

The equilibrium and linear fluid Magnetohydrodynamic (MHD) stability in an inward-shifted large helical device heliotron configuration are investigated with the 3D ANIMEC and TERPSICHORE codes, respectively. A modified slowing-down distribution function is invoked to study anisotropic pressure conditions. An appropriate choice of coefficients and exponents allows the simulation of neutral beam injection in which the angle of injection is varied from parallel to perpendicular. The fluid stability analysis concentrates on the application of the Johnson-Kulsrud-Weimer energy principle. The growth rates are maximum at beta 2%, decrease significantly at beta 4.5%, do not vary significantly with variations of the injection angle and are similar to those predicted with a bi-Maxwellian hot particle distribution function model. Stability is predicted at beta 2.5% with a sufficiently peaked energetic particle pressure profile. Electrostatic potential forms from the MHD instability necessary for guiding centre orbit following are calculated.

Keywords: LHD, Equilibrium, Stability, Anisotropy, Heliotron Reference EPFL-ARTICLE-182324doi:10.1063/1.4757635View record in Web of Science

Author: Cooper, W. A.; Asahi, Y.; Narushima, Y.; Suzuki, Y.; Watanabe, K. Y.; Graves, J. P.; Isaev, M. Yu.

Source: https://infoscience.epfl.ch/record/182324?ln=en

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