Role of the radial electric field in the transition from L (low) mode to H (high) mode to VH (very high) mode in the DIII-D tokamak
Journal Article
·
· Physics of Plasmas; (United States)
- General Atomics, P.O. Box 85608, San Diego, California 92186-9784 (United States)
The hypothesis of stabilization of turbulence by shear in the [ital E][times][ital B] drift speed successfully predicts the observed turbulence reduction and confinement improvement seen at the L (low)--H (high) transition; in addition, the observed levels of [ital E][times][ital B] shear significantly exceed the value theoretically required to stabilize turbulence. Furthermore, this same hypothesis is the best explanation to date for the further confinement improvement seen in the plasma core when the plasma goes from the H mode to the VH (very high) mode. Consequently, the most fundamental question for H-mode studies now is: How is the electric field [ital E][sub [ital r]] formed The radial force balance equation relates [ital E][sub [ital r]] to the main ion pressure gradient [del][ital P][sub [ital i]], poloidal rotation [ital v][sub [theta][ital i]], and toroidal rotation [ital v][sub [phi][ital i]]. In the plasma edge, observations show [del][ital P][sub [ital i]] and [ital v][sub [theta][ital i]] are the important terms at the L--H transition, with [del][ital P][sub [ital i]] being the dominant, negative term throughout most of the H mode. In the plasma core, [ital E][sub [ital r]] is primarily related to [ital v][sub [phi][ital i]]. There is a clear temporal and spatial correlation between the change in [ital E][times][ital B] shear and the region of local confinement improvement when the plasma goes from the H mode to the VH mode. Direct manipulation of the [ital v][sub [phi][ital i]] and [ital E][times][ital B] shear using the drag produced by a nonaxisymmetric magnetic perturbation has produced clear changes in local transport, consistent with the [ital E][times][ital B] shear stabilization hypothesis. The implications of these results for theories of the L--H and H--VH transitions will be discussed.
- DOE Contract Number:
- AC03-89ER51114; FG03-89ER51121; FG03-86ER53225
- OSTI ID:
- 5007258
- Journal Information:
- Physics of Plasmas; (United States), Journal Name: Physics of Plasmas; (United States) Vol. 1:5; ISSN PHPAEN; ISSN 1070-664X
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
70 PLASMA PHYSICS AND FUSION TECHNOLOGY
700310* -- Plasma Confinement-- (1992-)
700340 -- Plasma Waves
Oscillations
& Instabilities-- (1992-)
CLOSED PLASMA DEVICES
CONFINEMENT
ELECTRIC FIELDS
MECHANICAL PROPERTIES
PLASMA CONFINEMENT
SHEAR PROPERTIES
THERMONUCLEAR DEVICES
TOKAMAK DEVICES
TURBULENCE
700310* -- Plasma Confinement-- (1992-)
700340 -- Plasma Waves
Oscillations
& Instabilities-- (1992-)
CLOSED PLASMA DEVICES
CONFINEMENT
ELECTRIC FIELDS
MECHANICAL PROPERTIES
PLASMA CONFINEMENT
SHEAR PROPERTIES
THERMONUCLEAR DEVICES
TOKAMAK DEVICES
TURBULENCE