toroidal rotation in ecrh l-mode, i-phase and h-mode on hl-2a tokamak a.p. sun, j.q. dong, x.y. han,...
TRANSCRIPT
Toroidal rotation in ECRH L-mode, I-phase and
H-mode on HL-2A tokamak
A.P. Sun, J.Q. Dong, X.Y. Han, C.H. Liu, J.Y. Cao, M. Huang,
Y.G. Li, X. L. Huang and J.M. Gao
Southwestern Institute of Physics, China
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Outline
Introduction
Charge eXchange Recombination Spectroscopy (CXRS) in HL-2A tokamak
Toroidal rotation in HL-2A experiments with co-NBI
Toroidal rotation in ECRH L-mode discharges
Toroidal rotation in H-mode discharges
Toroidal rotation in I-phase of H-mode discharges
Summary
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Introduction
• Plasma toroidal rotation plays a key role in regulating turbulence and has a beneficial
effect on energy confinement in fusion devices.
•The toroidal rotation is studied on HL-2A in recent co-current direction NBI
experiments and charge exchange recombination spectroscopy (CXRS) is used to
measure its velocity profiles.
• Three cases are analyzed in this work.
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Charge exchange recombination spectroscopy in HL-2A tokamak
It is in the midplace at the low magnetic field side It has 8-13 channels Its spacial resolution is 3-5cm Its time resolution is 20ms
CXRS system sketch
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NBI starts at 410ms, end at 900ms.
ECRH first stage start at 522ms, second stage start at 675ms,
the last stage start at 828ms.
Toroidal rotation in HL-2A experiments with co-NBI
Toroidal rotation in ECRH L-mode discharge
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ECRH power deposition
After ECRH starts, toroidal rotation velocity decreases in the core plasma and near ECRH deposition position.
Toroidal rotation velocity changes little far away from ECRH deposition position.
Toroidal rotation velocity distribution vs time
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Toroidal rotation velocity decreases
significantly in the core plasma and
near ECRH deposition position.
Toroidal rotation velocity distribution vs R
The discharge parameters is similar to those in shot 19959, NBI and ECRH
starting and ending time is the same.
Toroidal rotation in ECRH L-mode discharge
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After ECRH starts, toroidal rotation
velocity decreases in the core plasma and
near ECRH deposition position.
Toroidal rotation velocity decreases
significantly in the core plasma and near
ECRH deposition position.
Toroidal rotation velocity distribution vs time Toroidal rotation velocity distribution vs R
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Toroidal rotation in H-mode discharges
Time evolutions of the core and edge toroidal rotation
• The toroidal rotation velocities increase significantly from L-mode to H-mode discharges
• The direction of edge toroidal rotation is reversed at the L-H transition
• Both core and edge toroidal rotations decrease at the H-L back transition.
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Toroidal rotation profiles in H-mode discharges
The toroidal rotation continuously increases from L-mode to H-mode, and decreases from
H-mode to L-mode. However, it is higher in the L-mode phase after H-L transition than
that before the L-H transition.
The toroidal rotation profiles at different stages
The black line represents the L-mode phase.
The red line does L-H transition stage.
The blue line shows the beginning of the first
ELM.
The green line does H-mode phase.
The purple line shows H-L transition stage.
The yellow line represents back to L-mode
stage.
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Toroidal rotation in I-phase and H-phase of H-mode discharges
The toroidal rotation velocities are compared between I-phase and H-phase The stored energy increases from I-
phase to H-phase. The toroidal rotation velocities in I-phase are lower than those in H-phase.
The red square symbols represent I-phase the blue circular symbols do H-phase.
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Summary
In ECH discharges, after ECRH starts, toroidal rotation velocity decreases
significantly in the core plasma and near ECRH deposition position, and changes little
far away from ECRH deposition position.
In H-mode discharges, the toroidal rotation continuously increases from L-mode to
H-mode, and decreases from H-mode to L-mode. However, it is larger in the L-mode
phase after H-L transition than that before the L-H transition.
In I-phase of H-mode discharges, the stored energy increases from I-phase to H-
phase, and the toroidal rotation velocities in I-phase are lower than those in H-phase.
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Thank you for your attention!