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Author(s):
N. Nakajima, C. Z. Cheng and M. Okamoto
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Title:
High-n Helicity-induced Shear Alfven Eigenmodes
Date of publication:
May 1992
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Key words:
Helicity-induced shear Alfven Eigenmodes (HAE), spectrum gap, Alfven continuum straight helical
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Abstract:
The high-n Helicity-induced shear Alfven Eigenmodes ( HAE ) are considered both analytically and numerically for the straight helical magnetic system, where n is the toroidal mode number. The eigenmode equation for the high-n HAE modes is derived along the field line and with the aid of the averaging method is shown to reduce to the Mathieu equation asymptotically. The discrete HAE modes are shown to exist inside the continuum spectrum gaps. The continuous spectrum gaps appear around omega^2 = omega_A^2 [N(l iotabar - m)/2]^2 for N = 1, 2, .., where omega_A is the toroidal Alfven transit frequency, and l, m, and iotabar are the polarity of helical coils, the toroidal pitch number of helical coils, and the rotational transform, respectively. For the same omega_A and iotabar, the frequency of the helical continuum gap is larger than that of the continuum gap in tokamak plasmas by | l - iotabar^-1m |. The polarity of helical coils l plays a crucial role in determining the spectrum gaps and the properties of the high-n HAE modes. The spectrum gaps near the magnetic axis are created by the helical ripple with circular flux surfaces for l = 1, and geq 3 helicals. For l = 2 helical systems, the spectrum gaps are created by the ellipticity of the flux surfaces. These analytical results for the continuum gaps and the existence of the high-n HAE modes in the continuum gaps are confirmed numerically for the l = 2 case, and we find that the HAE modes exist for mode structures with the even and the odd parities.
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