Radial acceleration of geodesic acoustic modes in the presence of a temperature gradient

被引:12
|
作者
Palermo, F. [1 ]
Poli, E. [1 ]
Bottino, A. [1 ]
Biancalani, A. [1 ]
Conway, G. D. [1 ]
Scott, B. [1 ]
机构
[1] EURATOM, Max Planck Inst Plasmaphys, Garching, Germany
来源
PHYSICS OF PLASMAS | 2017年 / 24卷 / 07期
关键词
ZONAL FLOWS; TURBULENCE; EXCITATION; DRIVEN; PLASMA; WAVES;
D O I
10.1063/1.4990074
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
The global dynamics of geodesic acoustic modes (GAMs) is studied analytically and by means of gyrokinetic simulations for several equilibria with flat and nonuniform profiles. In particular, the effects of phase mixing via the continuum spectrum in the presence of a temperature gradient are investigated. We show that the frequency of GAM is not constant but can evolve in time because of the increase of the radial wavenumber. As a consequence, also the radial velocity of GAM increases in time. Thus, this study reduces the discrepancy between the linear theory and the experiments, in which strong velocities of GAM are generally observed. An estimate of phase and group velocity is given for simulations performed with experimental parameter values. Published by AIP Publishing.
引用
收藏
页数:11
相关论文
共 50 条
  • [21] Geodesic acoustic modes in tokamak plasmas with anisotropic distribution and a radial equilibrium electric field
    Ming, Yue
    Zhou, Deng
    Wang, Wenjia
    PLASMA SCIENCE & TECHNOLOGY, 2018, 20 (08)
  • [22] Zonal geodesic acoustic modes in a high-temperature plasma tokamak
    A. B. Mikhailovskii
    A. P. Churikov
    V. D. Pustovitov
    Doklady Physics, 2010, 55 : 441 - 442
  • [23] Radial properties of the geodesic acoustic mode
    Li, Zhenqian
    Dong, Jiaqi
    Sheng, Zhengmao
    Yu, M. Y.
    Wang, Weixing
    PHYSICS OF PLASMAS, 2017, 24 (10)
  • [24] Eigenmode analysis of geodesic acoustic modes
    Gao, Zhe
    Itoh, K.
    Sanuki, H.
    Dong, J. Q.
    PHYSICS OF PLASMAS, 2008, 15 (07)
  • [25] Electromagnetic effects on geodesic acoustic modes
    Bashir, M. F.
    Smolyakov, A. I.
    Elfimov, A. G.
    Melnikov, A. V.
    Murtaza, G.
    PHYSICS OF PLASMAS, 2014, 21 (08)
  • [26] Collisionless damping of geodesic acoustic modes
    Sugama, H.
    Watanabe, T. -H.
    JOURNAL OF PLASMA PHYSICS, 2006, 72 : 825 - 828
  • [27] Drift effects on geodesic acoustic modes
    Sgalla, R. J. F.
    Smolyakov, A. I.
    Elfimov, A. G.
    Bashir, M. F.
    PHYSICS LETTERS A, 2013, 377 (3-4) : 303 - 306
  • [28] 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)
  • [29] Transverse acoustic oscillations in cylindrical chambers with the radial temperature gradient
    Fadeev, S. A.
    Saifutdinov, A. I.
    Kashapov, N. F.
    VII CONFERENCE ON LOW TEMPERATURE PLASMA IN THE PROCESSES OF FUNCTIONAL COATING PREPARATION, 2016, 669
  • [30] On nonlinear geodesic acoustic modes in tokamak plasmas
    Chen, Liu
    Qiu, Zhiyong
    Zonca, Fulvio
    EPL, 2014, 107 (01)
12345