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TJ-II:Influence of electron / ion root and ion mass on the radial and frequency structure of zonal flows in TJ-II: Difference between revisions
TJ-II:Influence of electron / ion root and ion mass on the radial and frequency structure of zonal flows in TJ-II (view source)
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== Name and affiliation of proponent == | == Name and affiliation of proponent == | ||
B. Liu [Southwest Jiaotong University | B. Liu [Southwest Jiaotong University, China], U. Losada, R. Gerrú, T. Kobayashi [NIFS], B. van Milligen, T. Estrada et al., | ||
== Details of contact person at LNF (if applicable) == | == Details of contact person at LNF (if applicable) == | ||
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In two plasmas produced by different heating (ECRH and NBI) schemes and characterized by different mean radial electric field structures, frequency-space-decomposed spectra of the global potential oscillation has been analyzed. In both cases, the oscillatory field has a monopole potential structure and a dipole radial electric field structure in the edge region. The width of the oscillating structure depends on its frequency as well as the heating scheme. As the frequency decreases, the oscillating structure asymptotically approaches to the mean profile. | In two plasmas produced by different heating (ECRH and NBI) schemes and characterized by different mean radial electric field structures, frequency-space-decomposed spectra of the global potential oscillation has been analyzed. In both cases, the oscillatory field has a monopole potential structure and a dipole radial electric field structure in the edge region. The width of the oscillating structure depends on its frequency as well as the heating scheme. As the frequency decreases, the oscillating structure asymptotically approaches to the mean profile. | ||
Whether this sensitive is due to the magnitude / sign of radial neoclassical electric fields affecting Reynolds stress driven ZFs, neoclassical mechanisms, plasma collisionality or / and fast particle effects remain an open question. | Whether this sensitive is due to the magnitude / sign of radial neoclassical electric fields affecting Reynolds stress driven ZFs, neoclassical mechanisms, plasma collisionality, plasma profile effects or / and fast particle effects remain an open question. | ||
== If applicable, International or National funding project or entity == | == If applicable, International or National funding project or entity == | ||
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== Description of required resources == | == Description of required resources == | ||
Required resources: | Required resources: | ||
* Number of plasma discharges or days of operation: | * Number of plasma discharges or days of operation: 3 days | ||
* Essential diagnostic systems:edge probes and HIBP | * Essential diagnostic systems:edge probes, Doppler and HIBP | ||
* Type of plasmas (heating configuration): ECRH in electron and ion root scenarios | * Type of plasmas (heating configuration): ECRH in electron and ion root scenarios | ||
* Specific requirements on wall conditioning if any: | * Specific requirements on wall conditioning if any: | ||
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== Preferred dates and degree of flexibility ==20-05-2018 | == Preferred dates and degree of flexibility ==20-05-2018 | ||
== References == | == References == | ||
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[[Category:TJ-II internal documents]] | [[Category:TJ-II internal documents]] | ||
[[Category:TJ-II experimental proposals]] | [[Category:TJ-II experimental proposals Spring 2018]] | ||