Your search keyword '"J.J. Koliner"' showing total 3 results

1. Identification of island-induced Alfvén eigenmodes in a reversed field pinch

Author

S.P. Hirshman, Chris Hegna, Jay Anderson, C. R. Cook, Donald A. Spong, J.J. Koliner, J. Boguski, Karsten McCollam, and R. Feng

Subjects

Physics, Reversed field pinch, business.industry, Condensed Matter Physics, 01 natural sciences, Madison Symmetric Torus, Neutral beam injection, Spectral line, 010305 fluids & plasmas, Computational physics, Coupling (physics), Optics, Nuclear Energy and Engineering, Physics::Plasma Physics, Normal mode, Harmonics, Physics::Space Physics, 0103 physical sciences, Pinch, 010306 general physics, business

Abstract

The modification of the shear Alfven spectrum due to a core resonant magnetic island is used to explain the Alfvenic activity observed on the Madison symmetric torus (MST) reversed-field pinch during neutral beam injection. Theoretical studies show that the Alfven continua in the core of the island provide a gap in which the observed Alfvenic bursts reside. Numerical simulations using a new code called SIESTAlfven have identified the bursts as the first observation of an island-induced Alfven eigenmode (IAE) in an RFP. The IAE arises from a helical coupling of harmonics due to the magnetic island.

Published

2016

2. Three dimensional equilibrium solutions for a current-carrying reversed-field pinch plasma with a close-fitting conducting shell

Author

J.J. Koliner, B. E. Chapman, D. L. Brower, J. Boguski, J. Duff, Mark Cianciosa, M.B. McGarry, James D. Hanson, Weixing Ding, Eli Parke, John Goetz, Lucas Morton, Jay Anderson, and D.J. Den Hartog

Subjects

Physics, Toroid, Reversed field pinch, Shell (structure), Plasma, Mechanics, Condensed Matter Physics, 01 natural sciences, Madison Symmetric Torus, 010305 fluids & plasmas, law.invention, Physics::Plasma Physics, law, 0103 physical sciences, Eddy current, Pinch, Atomic physics, Electric current, 010306 general physics

Abstract

In order to characterize the Madison Symmetric Torus (MST) reversed-field pinch (RFP) plasmas that bifurcate to a helical equilibrium, the V3FIT equilibrium reconstruction code was modified to include a conducting boundary. RFP plasmas become helical at a high plasma current, which induces large eddy currents in MST's thick aluminum shell. The V3FIT conducting boundary accounts for the contribution from these eddy currents to external magnetic diagnostic coil signals. This implementation of V3FIT was benchmarked against MSTFit, a 2D Grad-Shafranov solver, for axisymmetric plasmas. The two codes both fit Bθ measurement loops around the plasma minor diameter with qualitative agreement between each other and the measured field. Fits in the 3D case converge well, with q-profile and plasma shape agreement between two distinct toroidal locking phases. Greater than 60% of the measured n = 5 component of Bθ at r = a is due to eddy currents in the shell, as calculated by the conducting boundary model.

Published

2016

3. Fast ion confinement in the three-dimensional helical reversed-field pinch

Author

J.A. Reusch, S. Eilerman, J.J. Koliner, J. S. Sarff, L. Lin, Mark Nornberg, Jay Anderson, and W. Capecchi

Subjects

Physics, Nuclear Energy and Engineering, Reversed field pinch, Physics::Plasma Physics, Pinch, Magnetic confinement fusion, Atomic physics, Condensed Matter Physics, Helicity, Madison Symmetric Torus, Neutral beam injection, Charged particle, Ion

Abstract

Fast ions are well confined in the stochastic magnetic field of the multiple-helicity (MH) reversed-field pinch (RFP), with fast ion confinement times routinely a factor of 5 to 10 higher than thermal confinement time. Recent experiments have examined the behavior and confinement of beam-born fast ions in the three-dimensional (3D) helical RFP state. In lower current discharges, where the onset of the helical state is uncertain, high power neutral beam injection (NBI) tends to suppress the transition to the single helicity mode. In high current discharges (Ip ~ 0.5 MA), where the onset of n = 5 single helicity is quite robust, a short blip of NBI is used to probe the confinement of fast ions with minimal perturbation to the 3D equilibrium. The fast ion confinement time is measured to be substantially lower than fast ions in comparable MH RFP states, and there is a strong dependence on the strength of the helical perturbation. The established helical equilibrium is stationary in the laboratory frame but the locking occurs over the entire range of possible phase with respect to the Madison Symmetric Torus vessel. This effectively scans both the location of the NBI with respect to the helical structure and the pitch of the NBI-born fast ions. Fast ion confinement is observed to be insensitive to this angle, and in fact counter-NB injection into quasi-single helicity discharges shows fast ion confinement times similar to co-injection cases, in contrast to the MH RFP, where counter-injected fast ion confinement time is substantially lower.

Published

2014