Beam-driven energetic particle modes in advanced tokamak plasmas

W. W. Heidbrink; N. N. Gorelenkov; M. Murakami

doi:10.1088/0029-5515/42/8/305

Beam-driven energetic particle modes in advanced tokamak plasmas

W. W. Heidbrink, N. N. Gorelenkov, M. Murakami

PPPL Theory

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24 Scopus citations

Abstract

A major goal of the DIII-D program is to study 'advanced tokamak' plasmas with good confinement, large normalized β, and a large fraction of self-sustained current. Many of these plasmas have large beam pressures (≲1/3 of the total pressure) and weak magnetic shear; Alfvén instabilities with laboratory frequencies of 100-250 kHz are often observed. The instabilities correlate with reductions in the neutron rate below the classically expected value, complicating determination of the pressure and current profiles. Quantitative analysis of one case suggests that two types of energetic particle modes are destabilized: the resonant toroidicity-induced Alfvén eigenmode and the resonant kinetic ballooning mode. The strong dependence on neutral beam injection parameters and the variability in mode frequency are qualitatively consistent with this identification. Further analysis and measurements are planned.

Original language	English (US)
Pages (from-to)	972-976
Number of pages	5
Journal	Nuclear Fusion
Volume	42
Issue number	8
DOIs	https://doi.org/10.1088/0029-5515/42/8/305
State	Published - Aug 2002

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Condensed Matter Physics

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title = "Beam-driven energetic particle modes in advanced tokamak plasmas",

abstract = "A major goal of the DIII-D program is to study 'advanced tokamak' plasmas with good confinement, large normalized β, and a large fraction of self-sustained current. Many of these plasmas have large beam pressures (≲1/3 of the total pressure) and weak magnetic shear; Alfv{\'e}n instabilities with laboratory frequencies of 100-250 kHz are often observed. The instabilities correlate with reductions in the neutron rate below the classically expected value, complicating determination of the pressure and current profiles. Quantitative analysis of one case suggests that two types of energetic particle modes are destabilized: the resonant toroidicity-induced Alfv{\'e}n eigenmode and the resonant kinetic ballooning mode. The strong dependence on neutral beam injection parameters and the variability in mode frequency are qualitatively consistent with this identification. Further analysis and measurements are planned.",

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TY - JOUR

T1 - Beam-driven energetic particle modes in advanced tokamak plasmas

AU - Heidbrink, W. W.

AU - Gorelenkov, N. N.

AU - Murakami, M.

PY - 2002/8

Y1 - 2002/8

N2 - A major goal of the DIII-D program is to study 'advanced tokamak' plasmas with good confinement, large normalized β, and a large fraction of self-sustained current. Many of these plasmas have large beam pressures (≲1/3 of the total pressure) and weak magnetic shear; Alfvén instabilities with laboratory frequencies of 100-250 kHz are often observed. The instabilities correlate with reductions in the neutron rate below the classically expected value, complicating determination of the pressure and current profiles. Quantitative analysis of one case suggests that two types of energetic particle modes are destabilized: the resonant toroidicity-induced Alfvén eigenmode and the resonant kinetic ballooning mode. The strong dependence on neutral beam injection parameters and the variability in mode frequency are qualitatively consistent with this identification. Further analysis and measurements are planned.

AB - A major goal of the DIII-D program is to study 'advanced tokamak' plasmas with good confinement, large normalized β, and a large fraction of self-sustained current. Many of these plasmas have large beam pressures (≲1/3 of the total pressure) and weak magnetic shear; Alfvén instabilities with laboratory frequencies of 100-250 kHz are often observed. The instabilities correlate with reductions in the neutron rate below the classically expected value, complicating determination of the pressure and current profiles. Quantitative analysis of one case suggests that two types of energetic particle modes are destabilized: the resonant toroidicity-induced Alfvén eigenmode and the resonant kinetic ballooning mode. The strong dependence on neutral beam injection parameters and the variability in mode frequency are qualitatively consistent with this identification. Further analysis and measurements are planned.

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JO - Nuclear Fusion

JF - Nuclear Fusion

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ER -

Beam-driven energetic particle modes in advanced tokamak plasmas

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