R.D. Stambaugh scite author profile

An efficient method is given to reconstruct the current profile parameters, the plasma shape, and a current profile consistent with the magnetohydrodynamic equilibrium constraint from external magnetic measurements, based on a Picard iteration approach which approximately conserves the measurements. Computational efforts are reduced by parametrizing the current profile linearly in terms of a number of physical parameters. Results of detailed comparative calculations and a sensitivity study are described. Illustrative calculations to reconstruct the current profiles and plasma shapes in ohmically and auxiliarily heated Doublet III plasmas are given which show many interesting features of the current profiles.

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Separation of β̄_pand ℓ_iin tokamaks of non-circular cross-section

Lao¹,

John²,

Stambaugh³

et al. 1985

Nucl. Fusion

233

194

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Integral relations for the average poloidal beta J3 p and the plasma internal inductance 8j are derived from the magnetohydrodynamic (MHD) equilibrium equation for an axisymmetric torus. The volumedependent parameters that appear depend only weakly on the actual current density distribution inside the plasma and can be evaluated approximately, given the plasma shape and boundary poloidal magnetic field. In practice, these can be accurately and efficiently obtained for both diverted and limited plasmas from measured external poloidal magnetic field and flux values by approximating the plasma current distribution using a few filaments or distributed sources. For a tokamak plasma with a non-circular cross-section of sufficient elongation, J3 p and 8j can then be approximately determined separately. This is demonstrated for analytic equilibria of known shape as well as for actual Doublet III (D-III) plasmas for which /3 p and Z{ have been determined by using other methods. Results of a sensitivity study are described.

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Plasma shaping, edge ballooning stability and ELM behaviour in DIII-D

Ozeki¹,

et al. 1990

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The occurrence of giant edge localized modes (ELMs) in DIII-D has previously been correlated with the violation of the ballooning stability criterion at the plasma edge. These results are extended in the paper. It is demonstrated theoretically that flux surfaces near the separatrix of properly elongated and triangulated plasmas may be moved into the connection region between the first and second stability regions for ideal MHD ballooning modes, when q is high and the shear is low near the plasma surface. The edge flux surfaces are then predicted to have no limit to the sustainable pressure gradient. Experimentally, giant ELMs disappear in these highly shaped plasmas. However, the edge pressure gradient does not increase and ‘grassy’ ELM behaviour appears instead. These results lend further support to the hypothesis that giant ELMs in DIII-D are triggered by ideal ballooning mode instabilities, but they indicate that giant ELM and grassy ELM behaviour may arise from somewhat different mechanisms.

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Volt-second analysis and consumption in Doublet III plasmas

Ejima¹,

Callis²,

Luxon³

et al. 1982

Nucl. Fusion

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A Poynting's Theorem method is used for evaluating the volt-second consumption in a tokamak discharge. The method accurately identifies the inductive and resistive components of the volt-second consumption, and allows both quantities to be determined from magnetic measurements made outside the plasma. Only simple computational techniques are required. Application of the method to typical Doublet III nearcircular plasmas (R = 1.43 m, a = 0.44 m, b/a = 1.2) indicates that the flux at the plasma surface required to establish the current flat-top is 2.0 ± 0.2 V-s/MA. Approximately 40% of this flux is consumed in resistive dissipation. This division between resistive and inductive flux differs significantly from that obtained using an alternative data analysis method in which the resistive loss is evaluated at the plasma axis. The reasons for the difference are discussed.

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Scaling of energy confinement with minor radius, current and density in Doublet III Ohmically heated plasmas

Ejima

Pétrie

Riviere³

et al. 1982

Nucl. Fusion

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The dependence of plasma energy confinement on minor radius, density and plasma current is described for Ohmically heated near-circular plasmas in Doublet III. A wide range of parameters is used for the study of scaling laws; the plasma minor radius defined by the flux surface in contact with limiter is varied by a factor of 2 (a = 44, 32 and 23 cm) , the line average plasma density, n̄e, is varied by a factor of 20 from 0.5 to 10 × 1013 cm−3 (n̄e R0/BT = 0.3 to 6 × 1014 cm−2·kG−1) and the plasma current, I, is varied by a factor of 6 from 120 to 718 kA. The range of the limiter safety factor, qL, is from 2 to 12. – For plasmas with a = 23 and 32 cm, the scaling law at low n̄e for the gross electron energy confinement time can be written as (s, cm) where qc = 2πa2BT/μ0IR0. For the 44-cm plasmas, is about 1.8 times less than predicted by this scaling, possibly owing to the change in limiter configuration and small plasma-wall separation and/or the aspect ratio change. At high n̄e, saturates and in many cases decreases with n̄e but increases with I in a classical-like manner. The dependence of on a is considerably weakened. The confinement behaviour can be explained by taking an ion thermal conductivity 2 to 7 times that given by Hinton-Hazeltine's neoclassical theory with a lumped-Zeff impurity model. Within this range the enhancement factor increases with a or a/R0. The electron thermal conductivity evaluated at half-temperature radius where most of the thermal insulation occurs sharply increases with average current density within that radius, but does not depend on a within the uncertainties of the measurements.

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R.D. Stambaugh

Reconstruction of current profile parameters and plasma shapes in tokamaks

Separation of β̄_pand ℓ_iin tokamaks of non-circular cross-section

Plasma shaping, edge ballooning stability and ELM behaviour in DIII-D

Volt-second analysis and consumption in Doublet III plasmas

Scaling of energy confinement with minor radius, current and density in Doublet III Ohmically heated plasmas

Contact Info

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Resources

About

R.D. Stambaugh

Reconstruction of current profile parameters and plasma shapes in tokamaks

Separation of β̄pand ℓiin tokamaks of non-circular cross-section

Plasma shaping, edge ballooning stability and ELM behaviour in DIII-D

Volt-second analysis and consumption in Doublet III plasmas

Scaling of energy confinement with minor radius, current and density in Doublet III Ohmically heated plasmas

Contact Info

Product

Resources

About

Separation of β̄_pand ℓ_iin tokamaks of non-circular cross-section