Effect of temperature anisotropy on the dynamics of geodesic acoustic modes

被引:2
|
作者
Sama, J. N. [1 ]
Biancalani, A. [2 ,3 ]
Bottino, A. [3 ]
Chavdarovski, I. [4 ]
Del Sarto, D. [1 ]
Ghizzo, A. [1 ]
Hayward-Schneider, T. [3 ]
Lauber, Ph. [3 ]
Rettino, B. [3 ]
Vannini, F. [3 ]
机构
[1] Univ Lorraine, Inst Jean Lamour, CNRS, UMR 7198, F-54011 Nancy, France
[2] Leonard Vinci Pole Univ, Res Ctr, F-92400 Paris, France
[3] Max Planck Inst Plasma Phys, D-85748 Garching, Germany
[4] Korea Inst Fus Energy, Daejeon 34133, South Korea
来源
JOURNAL OF PLASMA PHYSICS | 2023年 / 89卷 / 01期
关键词
fusion plasma; plasma instabilities; plasma simulation; WAVES;
D O I
10.1017/S0022377823000016
中图分类号
O35 [流体力学]; O53 [等离子体物理学];
学科分类号
070204 ; 080103 ; 080704 ;
摘要
In this work, we revisit the linear gyro-kinetic theory of geodesic acoustic modes (GAMs) and derive a general dispersion relation for an arbitrary equilibrium distribution function of ions. A bi-Maxwellian distribution of ions is then used to study the effects of ion temperature anisotropy on GAM frequency and growth rate. We find that ion temperature anisotropy yields sensible modifications to both the GAM frequency and growth rate as both tend to increase with anisotropy and these results are strongly affected by the electron to ion temperature ratio.
引用
收藏
页数:15
相关论文
共 50 条
  • [31] The nonlinear dispersion relation of geodesic acoustic modes
    Hager, Robert
    Hallatschek, Klaus
    PHYSICS OF PLASMAS, 2012, 19 (08)
  • [32] Nonlinear dynamics of energetic-particle driven geodesic acoustic modes in ASDEX Upgrade
    Novikau, I.
    Biancalani, A.
    Bottino, A.
    Lauber, Ph.
    Poli, E.
    Manz, P.
    Conway, G. D.
    Di Siena, A.
    Ohana, N.
    Lanti, E.
    Villard, L.
    PHYSICS OF PLASMAS, 2020, 27 (04)
  • [33] Parametric Excitation of Geodesic Acoustic Modes by Electron Drift Waves and Ion Temperature Gradient Modes in Tokamak Plasmas
    Guzdar, P. N.
    Chakrabarti, N.
    Kleva, R. G.
    Kaw, P. K.
    Singh, R.
    Naulin, V.
    Rasmussen, J. J.
    THEORY OF FUSION PLASMAS, 2008, 1069 : 76 - +
  • [34] Dynamics of kinetic geodesic-acoustic modes and the radial electric field in tokamak neoclassical plasmas
    Xu, X. Q.
    Belli, E.
    Bodi, K.
    Candy, J.
    Chang, C. S.
    Cohen, R. H.
    Colella, P.
    Dimits, A. M.
    Dorr, M. R.
    Gao, Z.
    Hittinger, J. A.
    Ko, S.
    Krasheninnikov, S.
    McKee, G. R.
    Nevins, W. M.
    Rognlien, T. D.
    Snyder, P. B.
    Suh, J.
    Umansky, M. V.
    NUCLEAR FUSION, 2009, 49 (06)
  • [35] Characterization of geodesic acoustic modes in the ISTTOK edge plasma
    Silva, C.
    Duarte, P.
    Fernandes, H.
    Figueiredo, H.
    Nedzelskij, I.
    Hidalgo, C.
    Pedrosa, M. A.
    PLASMA PHYSICS AND CONTROLLED FUSION, 2009, 51 (08)
  • [36] Collisionless damping of short wavelength geodesic acoustic modes
    Qiu, Zhiyong
    Chen, Liu
    Zonca, Fulvio
    PLASMA PHYSICS AND CONTROLLED FUSION, 2009, 51 (01)
  • [37] Geodesic acoustic modes in noncircular cross section tokamaks
    E. A. Sorokina
    V. P. Lakhin
    L. V. Konovaltseva
    V. I. Ilgisonis
    Plasma Physics Reports, 2017, 43 : 271 - 279
  • [38] Relation between energetic and standard geodesic acoustic modes
    Girardo, Jean-Baptiste
    Zarzoso, David
    Dumont, Remi
    Garbet, Xavier
    Sarazin, Yanick
    Sharapov, Sergei
    PHYSICS OF PLASMAS, 2014, 21 (09)
  • [39] Geodesic acoustic modes in toroidally rotating tokamaks with an arbitrary β
    Ren, Haijun
    Li, Ding
    Chu, Paul K.
    PHYSICS OF PLASMAS, 2013, 20 (07)
  • [40] Transient excitation of zonal flows by geodesic acoustic modes
    Sasaki, M.
    Itoh, K.
    Ejiri, A.
    Takase, Y.
    PLASMA PHYSICS AND CONTROLLED FUSION, 2009, 51 (08)
12345