57th Annual Meeting of the APS Division of Plasma Physics
Volume 60, Number 19
Monday–Friday, November 16–20, 2015;
Savannah, Georgia
Session PI3: MHD and Rotation
2:00 PM–5:00 PM,
Wednesday, November 18, 2015
Room: Oglethorpe Auditorium
Chair: Guo-yong Fu, Princeton Plasma Physics Laboratory
Abstract ID: BAPS.2015.DPP.PI3.4
Abstract: PI3.00004 : Effect of Resonant Magnetic Perturbations on 3D equilibria in the MST RFP
3:30 PM–4:00 PM
Preview Abstract
Abstract
Author:
Stefano Munaretto
(Univ of Wisconsin, Madison)
The orientation of 3D, stellarator-like equilibria in the MST RFP can now be
controlled with application of an m $=$ 1 RMP. This has led to greatly
improved diagnosis, revealing enhancements in both the central electron
temperature and density. Coupled to a recent advance in the V3FIT code,
reconstructions of the 3D equilibria have also been dramatically improved.
The RMP also inhibits the generation of high-energy \textgreater 20 keV
electrons that is otherwise common with the 3D state. This state occurs when
the normally broad spectrum of core-resonant m $=$ 1 tearing modes
condenses, with the innermost resonant mode growing to large amplitude,
reaching $\sim$ 8{\%} of the axisymmetric field strength. This
occurs in plasmas of sufficiently large Lundquist number $\sim$
I$_{\mathrm{p}}$T$_{\mathrm{e}}$$^{3/2}$, and the duration of
the state is maximized with zero applied Bt (infinite toroidal beta). As the
dominant mode grows, eddy current in MST's conducting shell slows the mode's
rotation. This leads to locking of the 3D structure, but with an orientation
that varies randomly shot to shot, making diagnosis difficult. An m $=$ 1
RMP can now be applied with an array of saddle coils at the vertical
insulated cut in the shell. With an amplitude br/B $\sim$ 10{\%}
and a tailored temporal waveform, the RMP can force the 3D structure into
any desired orientation relative to MST's diagnostics. A recent advance in
V3FIT allows calculation of the substantial helical image current flowing in
MST's shell, which has in turn allowed self-consistent utilization of both
external and internal (Faraday rotation) measurements of the magnetic field.
The ORBIT code predicts reduced stochasticity and improved confinement of
high-energy electrons within the 3D structure. The suppression of these
electrons by the m $=$ 1 RMP may reflect a change to the central magnetic
topology. The generation of these electrons is unaffected by non-resonant
perturbations, such as m $=$ 3. Supported by the US DOE.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2015.DPP.PI3.4