Your search keyword '"null R. Majeski"' showing total 3 results

1. Recent Liquid Lithium Limiter Experiments in CDX-U

Author

null R. Majeski, null S. Jardin, null R. Kaita, null T. Gray, null P. Marfuta, null J. Spaleta, null J. Timberlake, null L. Zakharov, null G. Antar, null R. Doerner, null S. Luckhardt, null R. Seraydarian, null V. Soukhanovskii, null R. Maingi, null M. Finkenthal, null D. Stutman, null D. Rodgers, and null S. Angelini

Published

2005

2. Physics Considerations in the Design of NCSX

Author

null G.H. Neilson, null M.C. Zarnstorff, null L.P. Ku, null E.A. Lazarus, null P.K. Mioduszewski, null M. Fenstermacher, null E. Fredrickson, null G.Y. Fu, null A. Grossman, null P.J. Heitzenroeder, null R.H. Hatcher, null S.P. Hirshman, null S.R. Hudson, null D.W. Johnson, null H.W. Kugel, null J.F. Lyon, null R. Majeski, null D.R. Mikkelsen, null D.A. Monticello, null B.E. Nelson, null N. Pomphrey, null W.T. Reiersen, null A.H. Reiman, null P.H. Rutherford, null J.A. Schmidt, null D.A. Spong, and null D.J. Strickler

Subjects

Physics, business.industry, Nuclear engineering, Divertor, Ripple, Electrical engineering, National Compact Stellarator Experiment, Plasma, Collisionality, law.invention, law, Beta (plasma physics), Orbit (dynamics), business, Stellarator

Abstract

Compact stellarators have the potential to make steady-state, disruption-free magnetic fusion systems with beta approximately 5% and relatively low aspect ratio (R/ < 4.5) compared to most drift-optimized stellarators. Magnetic quasi-symmetry can be used to reduce orbit losses. The National Compact Stellarator Experiment (NCSX) is designed to test compact stellarator physics in a high-beta quasi-axisymmetric configuration and to determine the conditions for high-beta disruption-free operation. It is designed around a reference plasma with low ripple, good magnetic surfaces, and stability to the important ideal instabilities at beta approximately 4%. The device size, available heating power, and pulse lengths provide access to a high-beta target plasma state. The NCSX has magnetic flexibility to explore a wide range of equilibrium conditions and has operational flexibility to achieve a wide range of beta and collisionality values. The design provides space to accommodate plasma-facing components for divertor operation and ports for an extensive array of diagnostics.

Published

2002

3. Results of NSTX Heating Experiments

Author

null D. Mueller, null M. Ono, null M.G. Bell, null R.E. Bell, null M. Bitter, null C. Bourdelle, null D.S. Darrow, null P.C. Efthimion, null E.D. Fredrickson, null D.A Gates, null R.J. Goldston, null L.R. Grisham, null R.J. Hawryluk, null K.W. Hill, null J.C. Hosea, null S.C. Jardin, null H. Ji, null S.M. Kaye, null R. Kaita, null H.W. Kugel, null D.W. Johnson, null B.P. LeBlanc, null R. Majeski, null E. Mazzucato, null S.S. Medley, null J.E. Menard, null H.K. Park, null S.F. Paul, null C.K. Phillips, null M.H. Redi, null A.L. Rosenberg, null C.H. Skinner, null V.A. Soukhanovskii, null B. Stratton, null E.J Synakowski, null G. Taylor, null J.R. Wilson, null S.J. Zweben, null Y-K.M. Peng, null R. Barry, null T. Bigelow, null C.E. Bush, null M. Carter, null R. Maingi, null M. Menon, null P.M. Ryan, null D.W. Swain, null J. Wilgen, and null 37 additional authors

Subjects

Physics, Toroid, Physics::Plasma Physics, Beta (plasma physics), Torus, Plasma, Magnetohydrodynamics, Atomic physics, Scaling, Neutral beam injection, Bootstrap current

Abstract

The National Spherical Torus Experiment (NSTX) at Princeton is designed to assess the potential of the low-aspect-ratio spherical torus concept for magnetic plasma confinement. The plasma has been heated by up to 5 MW of neutral beam injection, NBI, at an injection energy of 90 keV and up to 6 MW of high harmonic fast wave, HHFW, at 30 MHz. NSTX has achieved beta T of 32%. A variety of MHD phenomena have been observed to limit eta. NSTX has now begun addressing E scaling, eta limits and current drive issues. During the NBI heating experiments, a broad Ti profile with Ti up to 2 keV, Ti > Te and a large toroidal rotation. Transport analysis suggests that the impurity ions have diffusivities approaching neoclassical. For L-Mode plasmas, E is up to two times the ITER-89P L-Mode scaling and exceeds the ITER-98pby2 H-Mode scaling in some cases. Transitions to H-Mode have been observed which result in an approximate doubling of tE. after the transition in some conditions. During HH FW heating, Te > Ti and Te up to 3.5 keV were observed. Current drive has been studied using coaxial helicity injection (CHI), which has produced 390 kA of toroidal current and HHFW, which has produced H-modes with significant bootstrap current fraction at low Ip, high q and high{sub etap}.

Published

2002