52nd Annual Meeting of the APS Division of Plasma Physics
Volume 55, Number 15
Monday–Friday, November 8–12, 2010;
Chicago, Illinois
Session TI2: Waves and Energetic Particles
9:30 AM–12:30 PM,
Thursday, November 11, 2010
Room: Grand Ballroom CD
Chair: Eric Fredrickson, Princeton Plasma Physics Laboratory
Abstract ID: BAPS.2010.DPP.TI2.4
Abstract: TI2.00004 : Investigation of LH Physics Through Power Modulation Experiments on C-Mod
11:00 AM–11:30 AM
Preview Abstract
Abstract
Author:
Andrea Schmidt
(MIT PSFC)
Lower hybrid current drive (LHCD) is an attractive tool for off-axis current
profile control in present devices and burning plasmas (ITER), because these
waves damp at high parallel phase speeds relative to the electron thermal
speed. The LHCD system on Alcator C-Mod operates at 4.6 GHz, with $\sim $
1MW of coupled power, and can produce spectra over a wide range of peak
parallel refractive index (n$\vert \vert )$.~ A 32 chord, horizontally
viewing hard x-ray camera has been used to measure the spatial and energy
distribution of fast electrons generated by LH waves, providing valuable
data for validating LHCD simulation models. Theory predicts that LH power
deposition location is strongly dependent on n$\vert \vert $. Square-wave
modulation of LH power on a time scale much faster than the current
relaxation time does not significantly alter the poloidal magnetic field
inside the plasma and thus allows for realistic modeling and consistent
plasma conditions for different n$\vert \vert $ spectra. Inverted hard
x-ray profiles show clear changes in LH-driven fast electron location with
differing n$\vert \vert $. Boxcar binning of hard x-rays during LH power
modulation allows for $\sim $ 1 ms time resolution, which is sufficient to
resolve the build-up, steady-state, and slowing-down phases of fast
electrons. The time histories of hollow x-ray profiles have been used to
measure a fast electron pinch velocity. Ray-tracing/Fokker-Planck modeling
in combination with a synthetic hard x-ray diagnostic show quantitative
agreement with the x-ray data at low densities. However, simulations do not
reproduce the experimentally observed LH density limit, above which the
x-ray count rates drop dramatically, unless strong absorption of the waves
in the plasma edge region is invoked. X-ray profile shapes suggest that LH
power is being deposited in the divertor region near the active x-point
location. Inclusion of a scrape-off layer in the ray tracing allows for a
detailed comparison of measured x-ray profiles with those predicted by
modeling. This work is supported by the US DOE awards DE-FC02-99ER54512 and
DE-AC02-76CH03073.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2010.DPP.TI2.4