Nonlinear evolution of the toroidal Alfvén instability using a gyrofluid model

D. A. Spong; B. A. Carreras; C. L. Hedrick

doi:10.1063/1.870700

Nonlinear evolution of the toroidal Alfvén instability using a gyrofluid model

D. A. Spong
, B. A. Carreras
, C. L. Hedrick

Research output: Contribution to journal › Article › peer-review

94 Scopus citations

Abstract

Discrete shear Alfvén modes such as the TAE (toroidal AlfVén eigenmode) are susceptible to destabilization by energetic alpha populations and neutral beams; this can lead to enhanced fast ion losses and degraded heating efficiencies. A gyrofluid model with Landau closure has been developed for understanding both the linear and nonlinear phases of these instabilities. The linear wave-particle resonances necessary to excite Alfvén instabilities are included in a coupled set of fluid equations. This model is used to analyze several nonlinear saturation mechanisms that arise from mode coupling effects. The effects of shear flow velocity generation (through the Reynolds stress) and localized current generation (leading to modifications in the q profile) are specifically examined.

Original language	English
Pages (from-to)	1503-1510
Number of pages	8
Journal	Physics of Plasmas
Volume	1
Issue number	5
DOIs	https://doi.org/10.1063/1.870700
State	Published - 1994

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@article{c425b3a0649844028a11d49d0fbb743a,

title = "Nonlinear evolution of the toroidal Alfv{\'e}n instability using a gyrofluid model",

abstract = "Discrete shear Alfv{\'e}n modes such as the TAE (toroidal AlfV{\'e}n eigenmode) are susceptible to destabilization by energetic alpha populations and neutral beams; this can lead to enhanced fast ion losses and degraded heating efficiencies. A gyrofluid model with Landau closure has been developed for understanding both the linear and nonlinear phases of these instabilities. The linear wave-particle resonances necessary to excite Alfv{\'e}n instabilities are included in a coupled set of fluid equations. This model is used to analyze several nonlinear saturation mechanisms that arise from mode coupling effects. The effects of shear flow velocity generation (through the Reynolds stress) and localized current generation (leading to modifications in the q profile) are specifically examined.",

author = "Spong, \{D. A.\} and Carreras, \{B. A.\} and Hedrick, \{C. L.\}",

year = "1994",

doi = "10.1063/1.870700",

language = "English",

volume = "1",

pages = "1503--1510",

journal = "Physics of Plasmas",

issn = "1070-664X",

publisher = "American Institute of Physics",

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T1 - Nonlinear evolution of the toroidal Alfvén instability using a gyrofluid model

AU - Spong, D. A.

AU - Carreras, B. A.

AU - Hedrick, C. L.

PY - 1994

Y1 - 1994

N2 - Discrete shear Alfvén modes such as the TAE (toroidal AlfVén eigenmode) are susceptible to destabilization by energetic alpha populations and neutral beams; this can lead to enhanced fast ion losses and degraded heating efficiencies. A gyrofluid model with Landau closure has been developed for understanding both the linear and nonlinear phases of these instabilities. The linear wave-particle resonances necessary to excite Alfvén instabilities are included in a coupled set of fluid equations. This model is used to analyze several nonlinear saturation mechanisms that arise from mode coupling effects. The effects of shear flow velocity generation (through the Reynolds stress) and localized current generation (leading to modifications in the q profile) are specifically examined.

AB - Discrete shear Alfvén modes such as the TAE (toroidal AlfVén eigenmode) are susceptible to destabilization by energetic alpha populations and neutral beams; this can lead to enhanced fast ion losses and degraded heating efficiencies. A gyrofluid model with Landau closure has been developed for understanding both the linear and nonlinear phases of these instabilities. The linear wave-particle resonances necessary to excite Alfvén instabilities are included in a coupled set of fluid equations. This model is used to analyze several nonlinear saturation mechanisms that arise from mode coupling effects. The effects of shear flow velocity generation (through the Reynolds stress) and localized current generation (leading to modifications in the q profile) are specifically examined.

UR - https://www.scopus.com/pages/publications/0041091476

U2 - 10.1063/1.870700

DO - 10.1063/1.870700

M3 - Article

AN - SCOPUS:0041091476

SN - 1070-664X

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SP - 1503

EP - 1510

JO - Physics of Plasmas

JF - Physics of Plasmas

IS - 5

ER -

Nonlinear evolution of the toroidal Alfvén instability using a gyrofluid model

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