5RV 1 Modeling of Plasmas on Computers: Past, Present, and Future.
J. Dawson, UCLA.
5IA 1 Transport Analysis of Gyrokinetic Tokamaks.
H.E. Mynick, Princeton
Plasma Physics Laboratory.
5IA 2 Advances in the Simulation of Toroidal Gyro-Landau Fluid Model
Turbulence.
R.E. Waltz, General Atomics.
5IA 3 Theory and Fluid Simulations of Turbulence in Boundary Plasmas.
X.Q. Xu, Lawrence Livermore National Laboratory.
5IB 1 Scaling and Transport Analysis of Divertor Conditions on the Alcator
C-Mod Tokamak.
B. Labombard, Massachusette Institute of Technology.
5IB 2 Helium Transport and Exhaust Studies in Enhanced Confinement Regimes
During Divertor Operation in DIII-D.
M.R. Wade, General Atomics.
5IB 3 Study of the Power Exhaust and the Role of Impurities in the TEXTOR
Tokamak.
A. Pospieszczyk, Institut fur Plasmaphysik, Germany.
5IB 4 Calculations of Radiation Losses in Divertors with Applications to
ITER.
D.E. Post, ITER, San Diego.
5E 1 X-ray driven ablation front hydrodynamic instability experiments on
Nova.
B.A. Remington, M.M. Marinak, S.V. Weber, S.G. Glendinning,
S.W. Haan, J.D. Kilkenny, G. Dimonte, and R.J. Wallace, LLNL,
Livermore, CA 94551.
5E 2 A Comparison of Imprinting of Drive Nonuniformities with 0.35 and
0.53 $\mu m$ Direct Drive.
S.G. Glendinning, S.V. Weber, S.N. Dixit,
M.A. Henesian, J.D. Kilkenny, D.M. Pennington, and R.J. Wallace,
University of California, LLNL, Livermore, CA 94551; J.P. Knauer and
C.P. Verdon, University of Rochester, LLE, Rochester, NY.
5E 3 Ablation Front Rayleigh-Taylor Instability: A Comparison between
Direct and Indirect Drive.
S. V. Weber, S.G. Glendinning, and B.A.
Remington, Lawrence Livermore National Laboratory.
5E 4 Growth of Low-Amplitude Mass Perturbations Due to the Rayleigh-
Taylor Instability.
J.P. Knauer, P.W. McKenty, and C.P. Verdon, LLE,
U. of Rochester; S.G. Glendinning, S.V. Weber, D.M. Pennington, and
R.J. Wallace, U. of California, LLNL.
5E 5 Model for Turbulent Mixing Width at an Ablating Surface.
Karnig O.
Mikaelian, Lawrence Livermore National Laboratory, Livermore,
California; Catherine Cherfils, Centre d'Etudes de Limeil-Valenton,
Villeneuve-St-Georges, France.
5E 6 Richtmyer-Meshkov Instability of Colliding Plasmas and Shock Waves.
Alexzander Velikovich, Berkeley Scholars, Inc.; and Lee Phillips,
Jill Dahlburg, Naval Research Laboratory.
5E 7 Oblique Shocks and Instabilities in Inertial-Confinement Fusion.
Arnold J. Sierk, Theoretical Division, Los Alamos National
Laboratory, Los Alamos, New Mexico 87945, USA.
5E 8 Richtmyer-Meshkov Experiments on Nova Laser.
Guy Dimonte, Eric
Frerking, and Bruce Remington, LLNL, Livermore, CA 94550.
5E 9 Perturbation growth due to rippled shock in Laser irradiated
corrugated foils -- Theory and Simulation.
A. Nishiguchi, Osaka
Institute of Technology; K. Mima, T. Endo, H. Azechi, and S. Nakai,
ILE Osaka Univ.
5E 10 Perturbation growth due to rippled shock in laser-irradiated
corrugated foils--Experiments.
H. Azechi, T. Endo, K. Shigemori, A.
Nishiguchi, K. Mima, M. Sato, M. Nakai, S. Nakaji, N. Miyanaga, S.
Matsuoka, A. Ando, S. Nakai, Institute of Laser Engineering, Osaka
University.
5E 11 The Effect of Thermal Conduction on the Ablative Rayleigh-Taylor
Instability.
V. Goncharov, R. Betti, R.L. McCrory, and C.P. Verdon,
LLE, U. of Rochester.
5F 1 Development of Transient Internal Probe (TIP) Magnetic Field
Diagnostic.
J.P. Galambos, M.A. Bohnet, T.R. Jarboe, A.T. Mattick,
University of Washington.
5F 2 The Thomson Scattering Diagnostic for the Tokamak ISTTOK.
M.P.
Alonso, P. Wilcock, K. Stammers, D. Trotman, J.A.C. Cabral, C.
Varandas, Associacao Euraton/IST, Portugal and UKAEA Fusion,
United Kingdom.
5F 3 Schlieren Photography of the Stuttering Current Sheet of Plasma
Focus Discharges.
K. Melzacki, V. Nardi, Stevens Inst. Techn.,
Hoboken, NJ 07030 USA.
5F 4 High Density Plasma Generation and Use in Large Caliber Electro-
thermal Chemical (ETC) Guns.
C. Marinos, R. Johnson, P. DiBona,
United Defense, L.P.
5F 5 Plasma Centrifugation at High Pressures.
E.R. Siciliano;
Westinghouse Hanford Co., and G. Rosenthal, A.Y. Wong, and R.F.
Wuerker, UCLA.
5F 6 Simulations of plasma ejection from JxB boundary layers.
S.B.
Swanekamp 1, J.M. Grossmann, J.D. Huba, A. Fruchtman 2, and P.F.
Ottinger, Plasma Physics Division, Naval Research Laboratory,
Washington, DC. 1=SAIC, McLean, VA; 2=Weizmann Institute of Science,
Rehovot, Israel.
5F 7 Rayleigh-Taylor Instability Analysis in the ICF-Spherical Pinch.
Haibo Chen, and B. Hilko, Advanced Laser and Fusion Technology,
Inc., P.O. Box 8763, Station "T", Ottawa, Canada K1G 3J1; D.P. Singh
and M. Vaselli, IFAM-CNR, Via de Giardino, 7, 56127 Pisa, Italy; F.
Giammanco, Dept. of Physics, University of Pisa, 56100 Pisa, Italy;
and E. Panarella, Dept. of Elect. and Comp. Eng., University of
Tennessee, Knoxville, TN 37996 USA.
5F 8 Spherically Pinched and Vacuum Spark Sources of X-Ray/EUV/FUV
Radiation.
E. Panarella, Dept. of Elect. and Comp. Eng., University
of Tennessee, Knoxville, TN 37996 USA; B. Hilko and H. Chen,
Advanced Laser and Fusion Technology, Inc., P.O. Box 8763, Station
"T", Ottawa, Canada K1G 3J1; D.P. Singh and M. Vaselli, IFAM-CNR,
Via de Giardino, 7, 56127 Pisa, Italy; and F. Giammanco, Dept. of
Physics, University of Pisa, 56100 Pisa, Italy.
5F 9 Electromagnetic Implosion of Spherical Liner.
J.H. Degnan, F.M.
Lehr, J.D. Beason 1, G.P. Baca, D.E. Bell, A.L. Chesley, S.K. Coffey
2, S. Dietz, D.B. Dunlap 3, S.E. Englert, T.J. Englert, D.G. Gale 3,
J.D. Graham 3, J.J. Havranek, C.D. Holmberg, T.W. Hussey, R.A. Lewis
4, C.A. Outten, R.E. Peterkin,Jr., D.W. Price, N.F. Roderick, E.L.
Ruden, U. Shumlak, G.A. Smith 4, P.J. Turchi. High Energy Plasma
Div., Phillips Lab, Kirtland AFB, NM. 1=US Air Force Academy,
Colorado Springs, CO; 2=Physical Sciences, Inc. Alexandria, VA;
3=Maxwell Laboratories, Inc., Albuquerque, NM; 4=Pennsylvania State
University, State College, PA.
5F 10 Loop Voltage Control in the Plasma Initiation Phase in FBX-II
Spherical Torus.
K. Numata, T. Naruse, M. Irie and FBX Group, Dept.
Elec. Engg. Waseda Univ.
5F 11 High Shear Spheromak / Spherical Reverse Field Pinch Operation of
FBX-II Spherical Torus.
M. Irie, K. Numata, T. Naruse, H. Kusma, H.
Yoshikawa, H. Somei, Dept. Elec. Engg. Waseda Univ.
5F 12 Surface cleaning techniques for the passive lithium-floride ion
source on the SABRE accelerator.
M.E. Cuneo, P.R. Menge, D.L.
Hanson, J.E. Bailey, M.A. Bernard, M.P. Disjarlais, A.B. Filuk,
W.E. Fowler, T.R. Lockner, S.A. Slutz, G.R. Ziska, Sandia National
Laboratories, Albuquerque, NM 87185-1193.
5F 13 An Inexpensive Microwave Plasma Source.
R. Jones, Physics Dept.,
Emporia State U., Emporia, KS.
5P 1 Steady State Performance Versus Shape in DIII-D.
A.W. Hyatt, E.A.
Lazarus, T.H. Osborne, and the DIII-D Team, General Atomics.
5P 2 The Effect of Elongation on Plasma Performance in DIII-D.
C.M.
Greenfield, J.C. DeBoo, T.H. Osborne, D. Boucher 1, F.W. Perkins 1,
M.N. Rosenbluth 1, J. Wesley 1, General Atomics. 1=ITER Joint
Central Team, San Diego, CA.
5P 3 Stabilization of Ideal MHD Kink Modes in DIII-D by a Resistive Wall
and Plasma Rotation.
A.D. Turnbull, T.S. Taylor, E.J. Strait, S.J.
Thompson, M.S. Chu, J.R. Ferron, L.L. Lao, B.W. Rice 1, O. Sauter 2,
R.T. Snider, D. Wroblewski 1, General Atomics. 1=Lawrence Livermore
National Laboratory; 2=CRPP/EPFL.
5P 4 The Dependence of the Beta Limit on the Current Density Profile in
an Advanced Tokamak Discharge Shape.
J.R. Ferron, L.L. Lao, T.H.
Osborne, E.J. Strait, T.S. Taylor, S.J. Thompson, A.D. Turnbull,
General Atomics.
5P 5 MHD Stability Analysis of High Beta DIII-D Discharges.
A.M. Popov,
E.J. Strait 1, A.D. Turnbull 1, Moscow University. 1=General
Atomics.
5P 6 The Dependence of Thermal Diffusivity on Density and Temperature.
D.P. Schissel, R. Maingi 1, and the DIII-D Team, General Atomics.
1=Oak Ridge National Laboratory.
5P 7 A Model for Heat Transport in the Interior of L- and H-mode Plasmas.
C. Hsieh, J.C. DeBoo, C.M. Greenfield, L.L. Lao, D.P. Schissel, H.E.
St. John, R. Stockdale, T.S. Taylor, General Atomics.
5P 8 Plasma Transport in the H-mode Regimes with Rising Density.
A.R.
Polevoi, M.V. Osipenko, Russian Research Center-Kurchatov Institute.
5P 9 Core Flow Shear as the Cause of the Veru High Confinement Regimes of
the DIII-D Tokamak.
R.J. La Haye, L.L. Lao, T.H. Osborne, and C.L.
Rettig 1, General Atomics. 1=University of California, Los Angeles.
5P 10 Investigations into Driving Perpendicular Flow with Off-Axis NBI in
the DIII-D Tokamak.
P. Gohil, K.H. Burrell, A.B. Hassam 1, and T.H
Osborne, General Atomics. 1=University of Maryland.
5P 11 Comparison of Experimental and Model Results for Magnetic Braking
in DIII-D.
T.H. Jensen, A.W. Hyatt, R.J. La Haye, General Atomics.
5P 12 Radial Electric Field Modification by Means of Lossy Counter NBI in
DIII-D.
J. Kim, R.D. Stambaugh, K.H. Burrell, G.T. Sager, and R.J.
Groebner, General Atomics.
5P 13 Transport Simulations of Confinement Improvement Through NBI Orbit
Loss.
R.D. Stambaugh, K.H. Burrell, J. Kim, F. Hinton, G.M.
Staebler, H.E. St. John, S.J. Thompson, J. Freeman, General Atomics.
5P 14 Momentum Transfer Events and the Transition to VH-mode.
T.H.
Osborne, K.H. Burrell, E.J. Doyle 1, C.M. Greenfield, R.J. Groebner,
C.L. Rettig 1, G.M. Staebler, T.S. Taylor, and the DIII-D Team,
General Atomics. 1=University of California, Los Angeles.
5P 15 Investigations of Microturbulence with Modified Radial Electric
Fields in the DIII-D Tokamak.
C.L. Rettig, W.A. Peebles, E.J. Doyle,
T.L. Rhodes, Institute of Plasma and Fusion Research and EE Dept.,
University of California, Los Angeles; K.H. Burrell, R.J. La Haye,
R.J. Groebner, T.S. Taylor, General Atomics.
5P 16 A Study of Edge Density Fluctuations by Phase Contrast Imaging on
DIII-D.
S. Coda 1, M. Porkolab 1, K.H. Burrell, General Atomics.
1=Department of Physics and Plasma Fusion Center, Massachusetts
Institute of Technology.
5P 17 Recent Results from the DIII-D Lithium Beam Diagnostic.
D.M. Thomas,
K.H. Burrell, T.E. Evans, General Atomics.
5P 18 Development of Advanced Optical Detection Techniques for Beam
Emission Spectroscopy on DIII-D.
R.D. Durst, R.J. Fonck, T.A.
Thorson, K. Tritz, University of Wisconsin/Madison; C. Greenfield,
General Atomics; S.F. Paul, Princeton University; Y. Karzhavin,
University of Texas/Austin.
5P 19 Current Profile Effects on Fast Ion Confinement in the DIII-D
Tokamak.
R.A. James 1, E.M. Carolipio 2, T.A. Casper 1, M.S. Chu, C.
M. Greenfield, W.W. Heidbrink 2, P.A. Politzer, B.W. Rice 1, H.E.
St. John, B.W. Stallard 1, E.J. Strait, A.D. Turnbull, General
Atomics. 1=Lawrence Livermore National Laboratory; 2=University
of California, Irvine.
5P 20 Time Dependent Modeling of High $\beta_{p}$ Discharges in DIII-D.
T.A. Casper 1, B.W. Stallard 1, J. Crotinger 1, S. Haney 1, H. St.
John, P.A. Politzer, General Atomics. 1=Lawrence Livermore National
Laboratory.
5P 21 Transport in High $\beta_{p}$ Discharges in DIII-D.
B.W. Stallard 1,
C.M. Greenfield, P.A. Politzer, and H. St. John, General Atomics.
1=Lawrence Livermore National Laboratory.
5P 22 Bootstrap and Neutral-Beam-Driven Currents in High $\beta_{p}$
Discharges in DIII-D.
P.A. Politzer, T. Casper 1, P. Gohil, A.W.
Hyatt, R.A. James 1, and B.W. Stallard 1, General Atomics.
1=Lawrence Livermore National Laboratory.
5P 23 BAE Modes in DIII-D and TFTR.
W.W. Heidbrink, E.M. Carolipio, R.
James 1, E.J. Strait 2, K.-L. Wong 3, University of California,
Irvine. 1=Lawrence Livermore National Laboratory; 2=General Atomics;
3=Princeton Plasma Physics Laboratory.
5P 24 The Effect of Helical Fields on Fusion-Product Confinement.
E.M.
Carolipio, W.W. Heidbrink, University of California, Irvine; R.J.
La Haye, General Atomics.
5P 25 Toward a Model of TAE-Induced Anomalous Fast Ion Diffusion in
DIII-D.
J.A. Fitzpatrick, Nuclear Engineering Department, University
of California at Berkeley, Berkeley, California 94720.
5P 26 The Dependence of Transport and Stability Properties of Reversed
Magnetic Shear Discharges on Energy Confinement Models.
H.E. St.
John, T.S. Taylor, Y. R. Lin-Liu, A.D. Turnbull, S.J. Thompson,
General Atomics.
5P 27 A Method for Measuring the Inductive Electric Field Profile and
Non-inductive Current Profiles on DIII-D.
C.B. Forest, K. Kupfer 1,
T.C. Luce, P.A. Polkitzer, L.L. Lao, D. Wroblewski 2, General
Atomics. 1=Orise Fellowship; 2=Maxwell Laboratory.
5P 28 DIII-D FWCD Antenna Operation with no Faraday Shield.
D.A. Swain 1,
F.W. Baity 1, D.B. Batchelor 1, S.C. Chiu, J.S. deGrassie, E.J.
Doyle 2, G.R. Hanson 1, K.W. Kim 2, R.I. Pinsker, C.C. Petty, C.L.
Rettig 2, J. Wilgen 1, General Atomics. 1=Oak Ridge National
Laboratory; 2=University of California, Los Angeles.
5P 29 Internal Measurements of RF Driven Waves Using Reflectometry on
DIII-D.
J.H. Lee, E.J. Doyle, S.C. Chiu 1, N.C. Luhmann,Jr 2, T.K.
Mau, W.A. Peebles, C.C. Petty 1, R.I. Pinsker 1, C.L. Rettig, and
T.L. Rhodes, IPFR and EE Dept., UCLA. 1=General Atomics;
2=University of California, Davis.
5P 30 Low Power Coupling of an Externally Tuned Traveling Wave Antenna to
Plasma in DIII-D.
D.A. Phelps, H. Ikezi, C.P. Moeller, R.I. Pinsker,
General Atomics.
5P 31 Experimental Disruption Studies in DIII-D.
P.L. Taylor, A.G.
Kellman, K. Holtrop, R.L. Lee, and D.A. Humpherys, General Atomics.
5P 32 Axisymmetric Simulation of Major Disruptions in ITER and DIII-D.
D.A. Humphreys, A.G. Kellman, R.R. Khayrutdinov 1, and V.E. Lukash
1, General Atomics. 1=TRINITI Laboratory.
5P 33 First results from the New Errof Field Correction Coil on DIII-D.
J.T. Scoville and R.J. La Haye, General Atomics.
5P 34 Alternate Basis Functions in EFIT.
W.H. Meyer and G.D. Porter,
Lawrence Livermore National Laboratory; L.L. Lao, General Atomics.
5Q 1 Characterization of Radiation Distribution During Radiative Divertor
Experiments.
A.W. Leonard, N.H. Brooks, M.E. Fenstermacher 1, D.N.
Hill 1, J.S. Kim 2, C.C. Klepper 3, C.J. Lasnier 1, W.H. Myer 1, and
T.W. Petrie, General Atomics. 1=Livermore National Laboratory;
2=University of California, San Diego; 3=Oak Ridge National
Laboratory.
5Q 2 Heat Flux Profiles in DIII-D Double-Null Radiative Divertors.
C.J.
Lasnier, D.N. Hill, S.L. Allen, R.A. Jong, A.W. Leonard 1, T.W.
Petrie 1, J. G. Watkins 2, Lawrence Livermore National Laboratory.
1=General Atomics; 2=Sandia National Laboratories.
5Q 3 Cryopump Operation and Wall Conditions on DIII-D.
P.K. Mioduszewski
2, R. Maingi 1, G.L. Jackson, M.A. Mahdavi, M.R. Wade 2, J.T. Hogan
2, L.W. Owen 2, and D.L. Hillis 2, General Atomics. 1=Oak Ridge
Associated Universities; 2=Oak Ridge National Laboratory.
5Q 4 Improved Low Heat Flux Operation in DIII-D Via Deuterium-Impurity
Hybrid Injection.
T.W. Petrie, S.A. Allen 1, D.N. Hill 1, N.H.
Brooks, D.A. Buchenauer 2, J.W. Cuthbertson 3, T.E. Evans, R.A.
James 1, C.J. Lasnier 1, A.W. Leonard, M.A. Mahdavi, M.J. Schaffer,
J.G. Watkins 2, W.P. West, D.G. Whyte 4, and R.D. Wood 1, General
Atomics. 1=Lawrence Livermore National Laboratory; 2=Sandia National
Laboratories; 3=University of California, San Diego; 4=Centre
Canadien de Fusion Magnetique.
5Q 5 Simultaneous Divertor Bias and Pump Experiments on DIII-D.
M.J.
Schaffer, D.A. Buchenauer 1, A.W. Hyatt, M.A. Mahdavi, R. Maingi 2,
and R.D. Wood 3, General Atomics. 1=Sandia National Laboratories;
2=Oak Ridge National Laboratory; Lawrence Livermore National
Laboratory.
5Q 6 Comparison of Non-Axisymmetric Effects in DIII-D Double and Single
Null Configurations.
T.E. Evans, C.J. Lasnier 1, D.N. Hill 1, A.W.
Leonard, and T.W. Petrie, General Atomics. 1=Lawrence Livermore
National Laboratory.
5Q 7 Production of Broad Scrape-off Layer Plasmas in DIII-D High
$\beta_{p}$ Experiments.
R.A. Jong, T.A. Casper, and C.J. Lasnier,
Lawrence Livermore National Laboratory.
5Q 8 Measurements of the C III Emission Distribution and Ion Temperature
in Radiative Divertor Experiments.
C.C. Klepper 1, N.H. Brooks, S.
Tugarinov, A.W. Leonard, and W.P. West, General Atomics. 1=Oak Ridge
National Laboratory.
5Q 9 Divertor Langmuir Probe Measurements at High Power in DIII-D.
D.A.
Buchenauer 1, J.W. Cuthbertson 2, J.A. Whaley 1, J.G. Watkins 1, and
D.N. Hill 3, General Atomics. 1=Sandia National Laboratory;
2=University of California, San Diego; 3=Lawrence Livermore National
Laboratory.
5Q 10 Simulation of Some Radiative Divertor Options for DIII-D.
M.E.
Rensink, M.E. Fenstermacher, G.D. Porter, T.D. Rognlien, G.R. Smith,
Lawrence Livermore National Laboratory.
5Q 11 Multi-Fluid Simulation of DIII-D Edge Plasma.
A. Yu. Pigarov, V.A.
Pozharov, T.W. Petrie 1, Russian Research Center-Kurchatov
Institute. 1=General Atomics.
5Q 12 Modeling of Impurity Transport in the DIII-D Radiative Divertor with
the MCI Code.
G.T. Sager, T.E. Evans, and W.P. West, General
Atomics.
5Q 13 Modeling of the DIII-D SOL with the 2-D Fluid Code UEDGE.
Q. Nguyen,
T.K. Fowler, U.C. Berkeley; G.D. Porter, T.D. Rognlien, M.E.
Rensink, D.N. Hill, Lawrence Livermore National Lab.
5Q 14 Analysis of DIII-D SOL Experiments Using the Fluid Code UEDGE.
G.D.
Porter, and the DIII-D Team, Lawrence Livermore National Laboratory.
5Q 15 Character of the DIII-D Double-Null Scrape-Off Layer.
J.G. Watkins,
R.A. Moyer 1, R.A. Jong 2, R.J. La Haye, T.E. Evans 3, D.N. Hill 2,
and R.D. Stambaugh 3, Sandia National Laboratories. 1=University of
California, San Diego; 2=Lawrence Livermore National Laboratory;
3=General Atomics.
5Q 16 Time Dependent Particle Transport Studies During the Density
Increase in H-mode and VH-mode DIII-D Plasmas.
D.R. Baker, K.H.
Burrell, G.L. Jackson, R. Maingi 1, G.M. Staebler, and C.B. Forest,
General Atomics. 1=Oak Ridge National Laboratory.
5Q 17 A Survey of DIII-D Core Impurity Concentrations.
D.G. Whyte 1, W.P.
West, S.I. Lippmann 2, N.H. Brooks, R.D. Wood 3, D.K. Finkenthal 4,
General Atomics. 1=Centre Canadien de Fusion Magneitque; 2=7370-120
Calle Cristobal, San Diego, California; 3=Lawrence Livermore
National Laboratory; 4=University of California, Berkeley.
5Q 18 Impurity Studies During Radiative Divertor Experiments on DIII-D.
R.D. Wood 1, S.L. Allen 1, T.W. Petrie, D.N. Hill 1, N.H. Brooks, S.
Tugarinov 2, W.P. West, M.E. Fenstermacher 1, C.J. Lasnier 1, C.C.
Klepper 1, M.A. Mahdavi, G.R. Smith 1, G.D. Porter 1, General
Atomics. 1=Oak Ridge National Laboratory; 2=TRINITI Laboratory.
5Q 19 Modeling of Global Particle Confinement in ELM-free H-Mode
Discharges in DIII-D.
L.W. Owen, R. Maingi, D.K. Lee, P.K.
Mioduszewski, D.L. Hillis, J.T. Hogan, M.R. Wade, Oak Ridge National
Laboratory, Oak Ridge, Tennessee 37831-8058; D.R. Baker, and G.L.
Jackson, General Atomics Inc., San Diego, California 92138.
5Q 20 Initial Results from Deuterium Pellet Injection Experiments in
DIII-D.
L.R. Baylor, T.C. Jernigan, S.K. Combs, C.R. Foust, W.A.
Houlberg, S.L. Milora, M.R. Wade, J.C. Phillips 1, and D.P.
Schissel 1, Oak Ridge National Laboratory. 1=General Atomics.
5Q 21 Simulation of Current Profile Control in DIII-D Using Pellet Fueling
and RF Heating.
S.E. Attenberger and W.A. Houlberg, Oak Ridge
National Laboratory, Oak Ridge, Tennessee 37831-8058.
5R 1 Experimental observation of chaos in negative ions plasma.
W.X.
Ding, D.L. Feng, W. Huang, J. Zheng, Y. Jiang, C.X. Yu, Department
of Modern Physics, University of Science and Technology of China,
Hefei,230026, P.R.China.
5R 2 Turbulence-Induced Stark Effects in Collisional Ionizing Shock
Waves.
J.A. Johnson III, A. Lee, A. Ivory, L.E. Johnson and R.L.
Williams, Florida A&M Univ.
5R 3 Subgrid Modelling of Convective Turbulence In Weakly Ionized
Collisional Plasma By Renormalization Group Analysis.
A.M. Hamza,
University of Western Ontario, Canada and R.N. Sudan, Cornell
University, Ithaca, NY.
5R 4 Self-Consistency Constraints on the Dynamo Mechanism.
Y. Yuan and
A. Bhattacharjee, U. of Iowa.
5R 5 Finite-Time Vortex Singularity and the Kolmogorov Spectrum in a 3D
Spiral Model.
Chung-Sang Ng, Xiaogang Wang, and A. Bhattacharjee,
U. of Iowa.
5R 6 Intermittency, realizable stochastic models, and plasma turbulence.
J.A. Krommes and G. Hu, Princeton University.
5R 7 Nonlinear transport in resistive drift wave turbulence.
G. Hu, J.A.
Krommes, Princeton U., and J.C. Bowman, U. of Texas at Austin.
5R 8 Transport in Chaotic Systems.
A.H. Boozer and X.Z. Tang, William and
Mary.
5R 9 A Computational Study of the Dynamics of Hydrodynamic Trapped Ion
Temperature Gradient Driven Turbulence.
D.E. Newman and B.A.
Carreras, ORNL and P. H. Diamond, UCSD.
5R 10 Spatio-Temporal Measurements of the Transition to Turbulence in
Drift-Waves.
T. Klinger, A. Latten, and A. Piel, Christian-
Albrechts-Universitat, Kiel (Germany).
5R 11 Reconstruct Noisy Chaotic Signals.
X.Z. Tang, E.R. Tracy, M. Lane,
A. Joshua, William & Mary; R. Brown, UCSD.
5R 12 Wave-vortex interactions and self--organization in a simple model of
plasma 2D turbulence.
X. Leoncini, A.D. Verga, Equipe Turbulence
Plasma, Institut Mediterraneen de Technologie, 13451 Marseille Cedex
20.
5R 13 Magnetic Field Effect on Plasma Turbulent Bremsstrahlung.
O. Ishihara, Texas Tech University.
5R 14 Turbulence Modeling by Thermo-Lattice Boltzmann Techniques.
G. Vahala, William & Mary; P. Pavlo, Institute of Plasma Physics,
Czech Rep., L. Vahala, Old Dominion University; H. Chen, Exa Corp.
5R 15 Nonlinear Wave-Particle Interaction leading to Chaotic Ion Motion in
the Magnetosphere.
S.P. Kuo and A.Y. Hol 1, Weber Research
Institute, Polytechnic University, Route 110. Farmingdale, NY 11735.
1=Now at TRW Inc., Redondo Beach, CA.
5R 16 Improved Confinement in DIII-D Due to Rotational Flow: A Comparison
Between Theory and Experiment.
R.R. Dominguez, R.E. Waltz, A.
Brizard 1, M. Kotschenreuther 2, R.J. La Haye, General Atomics.
1=University of California at Berkeley; 2=IFS/The University of
Texas at Austin.
5R 17 Investigations of wavenumber-reduction schemes.
J.C. Bowman and P.
J. Morrison, Institute for Fusion Studies.
5R 18 Random Sources, Active Control, and Predator-Prey L to H Transition
Models.
Y.E. Ko 1, G.G. Craddock 2, T.S. Hahm, and P.H. Diamond 1,
Princeton University. 1=University of California at San Diego;
2=NERSC, Lawrence Livermore National Laboratory.
5R 19 Mode-Coupling Measurements on the Bump-On-Tail Instability.
D.A.
Hartmann, C.F. Driscoll, T.M. O'Neil and V.D. Shapiro, Univ. of
Calif., San Diego.
5R 20 Fusion-Ash Removal Scheme Using Bucket Dynamics Produced by Chirped
Waves.
C.T. Hsu, Per Helander, C.Z. Cheng, and D.J. Sigmar, Plasma
Fusion Center, M.I.T.
5R 21 Nonlinear Evolution, Multiscale Coupling and Transport in the
Drift-Kelvin-Helmholtz Instability.
M.J. Keskinen, Plasma Physics
Division, Naval Research Laboratory.
5R 22 Turbulence in Systems with Finite Cross-Helicity,
E. A. Novakovski
1, and S. V. Novakovski, Institute for Plasma Research, University
of Maryland, College Park, MD 20742-3511.
5R 23 Control of Chaotic Systems through Small Periodic Parametric
Perturbations.
K.A. Mirus, J.C. Sprott, University of Wisconsin-
Madison.
5R 24 2D-MHD Forced by Low Frequency Tearing Instability.
E. Fernandez and
P.W. Terry, University of Wisconsin-Madison.
5R 25 Diamagnetic Modifications of the Alfvenic Turbulent State.
P.W.
Terry and A. S. Ware, University of Wisconsin-Madison.
5R 26 Self-regulating Ion Temperature Gradient Turbulence.
A.S. Ware, P.
W. Terry, University of Wisconsin-Madison, and P.H. Diamond,
University of California at San Diego.
5R 27 Measurement of 2-Dimensional Perpendicular Velocity Distribution of
Stochastic Ions.
S.J. Sanders, R.A. Granat, P.M. Bellan, Caltech,
and R.A. Stern, U. of Col.
5R 28 Sheared Poloial Flows and Radial Electric Fields: Detailed
Fluctuation Measurements in PICES-A.
R.D. Lehmer, L. Schmitz, Y.-Q.
Tao, and R.W. Conn 1, Institute of Plasma and Fusion Research, UCLA.
1=School of Engineering, UC-San Diego.
5R 29 Coherent structures and turbulent cascades in two-dimensional
magnetohydrodynamic turbulence.
R. Kinney, J.C. McWilliams, Natl.
Center for Atmos. Research, Boulder, Co 80303 and T. Tajima,
University of Texas at Austin, Austin, TX 78712.
5R 30 Chaotic Dynamics of Periodically Kicked NLS Soliton.
R Uma, H.
Singh, and D. Subbarao and B. Buti 1, Indian Institute of
Technology, Delhi, New Delhi 110016. 1=National Physical Laboratory,
New Delhi 110012.
5R 31 New Properties of the Ergodic Layer.
S.S. Abdullaev and G.M.
Zaslavsky, Courant Institute and Physics Dept., New York University.
5R 32 Modeling of a Chaotic Signal.
M. Lehrman and A.B. Rechester,
Institute of Nonlinear Science Applications; R.B. White, Princeton
Plasma Physics Laboratory.
5R 33 Electromagnetic Wave Interaction with Beam-Plasma Induced
Turbulence.
J. Masten and O. Ishihara, Texas Tech University.
6IA 1 Recent Progress of High-Power Millimeter Wave Gyrodevices.
A. Litvak, Institute of Applied Physics, Russia.
6IA 2 Discharge-Pumped Soft-X-Ray Laser in Ne-like Ar.
J.J. Rocca,
Colorado State University.
6IA 3 Optimization of X-ray Emission in Z-pinch Implosions: Theory versus
Experiment.
K.G. Whitney, Naval Rasearch Laboratory.
6IB 1 Experimental Studies of Charged Dust Particles.
S.H. Robertson,
University of Colorado, Boulder.
6IB 2 Dissipative Caviton of the Lower Hybrid Waves and Ion Acceleration
Observed in Auroral Ionosphere.
V.D. Shapiro, University of
California, San Diego.
6IB 3 Recent Observations of a Variety of Optical Emissions Extending
Upward From the Tops of Thunderstorms to the Stratosphere,
Mesosphere, and Ionosphere.
D.D. Sentman, University of Alaska,
Fairbanks.
6E 1 Study of parametric instabilities in large-scale-length plasrmas.
B.J. MacGowan, C.A. Back, R.L. Berger, K.S. Bradley, K.G. Estabrook,
B.H. Failor 1, W.W. Hsing 1, D.H. Kalantar, R.L. Kauffman, R.K.
Kirkwood, D.E. Klem, W.L. Kruer, J.L. Miller; D.S. Montgomery, J.D.
Moody, D.H. Munro, T.J. Murphy, L.V. Powers, T.D. Shepard, G.F.
Stone, S.C. Wilks, and E.A. Williams, Lawrence Livermore National
Laboratory, University of California, L-447 P.O. Box 808, Livermore,
CA 94550, U.S.A. 1=Los Alamos National Laboratory, University of
California, Los Alamos NM 87545, U.S.A.
6E 2 Simulations of Nova Gas-Filled Hohlraum Experiments.
L.V. Powers, C.
A. Back, R.L. Berger, D.H. Kalantar, R.L. Kauffman, B.F. Lasinski,
D.S. Montgomery, D.H. Munro, T.D. Shepard, G.F. Stone, R.E. Turner
and E.A. Williams, Lawrence Livermore National Laboratory.
6E 3 SBS Experiments on Nova Using Large Gas-Filled Hohlraums.
R.E.
Turner, C.A. Back, R.L. Berger, R.L. Kauffman, D.H. Kalantar, D.E.
Klem, B.F. Lasinski, B.J. MacGowan, D.S. Montgomery, L.V. Powers, T.
D. Shepard, and G.F. Stone, Lawrence Livermore National Laboratory.
6E 4 The Design of Toroidal-shaped NOVA Hohlraums that Simulate National
Ignition Facility Plasma Conditions for Plasma Instability
Experiments.
B.H. Wilde, J.C. Fernandez, W.W. Hsing, Los Alamos
National Laboratory.
6E 5 Comparative Study of Brillouin Backscatter from Nova Hohlraums.
J.C.
Fernandez, K.S. Bradley, J.A. Cobble, N.D. Delamater, B.H. Failor 2,
P.L. Gobby, R.G. Hockaday, W.W. Hsing, E.L. Lindman, D.A. Montgomery
1, B.H. Wilde, M.D. Wilke, Los Alamos National Lab. 1=Lawrence
Livermore National Lab.; 2=Physics International.
6E 6 Stimulated Brillouin Scattering in Long-Scale-Length, Preformed
Plasmas at 1 $\mu m$: Experiments and Simulations.
W. Seka, A.V.
Chirokikh, R.S. Craxton, and R.E. Bahr, LLE, U. of Rochester. USA;
C. Labaune, H.A. Baldis, N. Renard, E. Schifano, A. Michard, and
S. Baton, LULI, Ecole Polytechnique, France; B. Bauer, K. Baker, and
R.P. Drake, Plasma Physics Research Institute, Livermore, USA; K.
Estabrook, Lawrence Livermore National Laboratory, USA.
6E 7 Observations and Simulation of Stimulated Brillouin Scattering in
Long-Scale-Length Laser Plasmas.
A.V. Chirokikh, W. Seka, R.E. Bahr,
R.S. Craxton, R.W. Short, A. Simon, and M.D. Skeldon, LLE, U. of
Rochester.
6E 8 The Effects of Realistic Geometry on Two-Dimensional Stimulated
Brillouin Scattering.
T. Kolber, C.J. McKinstrie, R. Betti, and R.
E. Giacone, LLE, U. of Rochester.
6E 9 Stimulated Brillouin backscattering from nonuniform and filamented
laser beams in stationary and flowing plasmas.
R.L. Berger, B.B.
Afeyan, B.I. Colhen, T. Kaiser, A. B. Langdon, B.F. Lasinski, C.H.
Still, and E.A. Williams, Lawrence Livermore National Laboratory.
6E 10 Effect on the angular distribution of Brillouin backscattered light
of filamentation and finite laser spot size.
B.F. Lasinski, A.B.
Langdon, B.B. Afeyan, R.L. Berger, B.I. Cohen, T.B. Kaiser, C.H.
Still, S.C. Wilks, and E.A. Williams, Lawrence Livermore National
Laboratory.
6E 11 Stimulated Brillouin Scattering and Self-Focusing Instability Driven
by Gaussian Beams.
V. Eliseev 1, W. Rozmus, V. T. Tikhonchuk 2,
Department of Physics; C.E. Capjack, Department of Electrical
Engineering, University of Alberta, Edmonton, Canada. 1=On leave
from General Physics Institute; 2=P.N. Lebedev Physics Institute,
Moscow, Russia.
6E 12 Efficient Production of 1-15 keV x rays by Laser Heated
"Underdense Radiators".
L.J. Suter, R.L. Kauffman, and M. Tobin,
Lawrence Livermore National Laboratory.
6E 13 X-ray Production in laser-heated Xe gas targets.
R.L. Kauffman, L.
J. Suter, H.N. Kornblum, D.S. Montgomery, and T.E. Orzechowski,
Lawrence Livermore National Laboratory, Livermore, CA 94551.
6F 1 Nonlinear Calculations of Core Fluctuations with Gyro-Landau Fluid
Models.
J.G. Leboeuf, C.L. Hedrick, V.E. Lynch, K.L. Sidikman, D.A.
Spong, ORNL; and R.D. Sydora, UCLA.
6F 2 Progress in Nonlinear Gyrofluid Turbulence Simulations.
S.W.
Hammett, M.A. Beer, W.D. Dorland (Inst. for Fusin Studies), S.A.
Smith, R.E. Waltz (General Atomics), Princeton University Plasma
Physics Laboratory.
6F 3 Gyrokinetic Zero-Electron-Mass Hybrid Model.
S.E. Parker, L. Chen 1,
W.W. Lee, Princeton University Plasma Physics Laboratory.
1=University of California at Irvine.
6F 4 Generation and Damping of Sheared Perpendicular Flows in
Electrostatic Toroidal Syrokinetic Particle Simulaitons of
$\eta_{i}$ Mode Turbulence.
J.C. Cummings, W.W. Lee and S.E. Parker,
Princeton Plasma Physics Laboratory.
6F 5 Detailed Comparisons of Nonlinear Gyrofluid ITG Simulations and
Experiment.
W. Dorland, M. Kotschenreuther, M.A. Beer 1, G.W.
Hammett 1, D. Mikkelsen 1, and J.Q. Dong, Insitutue for Fusion
Studies. 1=Princeton Plasma Physics Laboratory.
6F 6 Gyrokinetic Particle Simulation of Multi-Hydrogenic-Ion Plasmas.
W.W. Lee, R.A. Santoro 1, S.E. Parker, and H.P. Furth, Princeton
Plasma Physics Laboratory. 1=University of California at Irvine.
6F 7 Verificatin of a Canonical Profile Transport Model.
Yu.N.
Dnestrovskij, S.E. Lysenko, K.N. Tarasian, Russian Research Centre
"Kurchatov Institute," Moscow, Russia.
6F 8 The Effect of "Shape" on the Ion Temperature Gradient Instability.
J.U. Brackbill and G. Lapenta, Los Alamos National Laboratory, Los
Alamos, NM 87545.
6F 9 Turbulence Calculations with Self-Consistent Background Profiles.
A.I. Shestakov, R.H. Cohen, X.Q. Xu, J.A. Crotinger, L.L. LoDestro,
LLNL.
6P 1 Transport Results from Alcator C-Mod.
M. Greenwald and Alcator Group
MIT Plasma Fusion Center.
6P 2 Local Transport Analysis for Alcator C-Mod.
J. Schachter, M.
Greenwald, and the Alcator Group, MIT Plasma Fusion Center.
6P 3 Transport Simulation of Alcator C-Mod Ohmic Plasmas.
W. Daughton, B.
Coppi, L.E. Sugiyama, M. Greenwald, and the Alcator C-Mod Team,
M.I.T.
6P 4 Global Thermal Transport: Current and Density Dependence.
L.E.
Sugiyama, B. Coppi, W. Daughton, M. Greenwald, and the Alcator C-Mod
Team, M.I.T.
6P 5 ICRF Heating Results in the Alcator C-Mod Tokamak.
S.N. Golovato, M.
Porkolab, Y. Takase, and the Alcator C-Mod Group, MIT Plasma Fusion
Center.
6P 6 Analysis of ICRF Antenna Loading Measurements in Alcator C-Mod.
W.C.
Guss, P.T. Bonoli, S.N. Golovato, M. Porkolab, Y. Takase, MIT Plasma
Fusion Center.
6P 7 RF Edge Probes in the Alcator C-Mod Tokamak.
J. Reardon, S.N.
Golovato, B. Labombard, P. O'Shea, M. Porkolab, Y. Takase and the
Alcator C-Mod Group, MIT Plasma Fusion Center.
6P 8 Design of the PPPL-MIT four strap antenna for Alcator C-Mod.
J.C.
Hosea, P. Bonanos, L. Gereg, R. Majeski, J.H. Rogers, G. Schilling,
J.R. Wilson, PPPL; S.N. Golovato, M. Porkolab, Y. Takase, MIT.
6P 9 Fast Temperature Measurements on Alcator C-Mod Using a Nine Channel
ECE Polychromator.
P.J. O'Shea, A.E. Hubbard, MIT Plasma Fusion
Center.
6P 10 Density Measurements with Amplitude Modulated Reflectometry on
Alcator C-MOD.
P.C. Stek, J.H. Irby, MIT Plasma Fusion Center.
6P 11 Determination of q-profiles in Alcator C-Mod Using X-ray Imaging.
C.
Borras and R.S. Granetz, MIT Plasma Fusion Center.
6P 12 Evolution of the Alcator C-Mod Shape Control System.
S. Horne, S.N.
Golovato, I. Hutchinson, J. Irby, S. Wolfe, M. Fridberg, J.
Stillerman, G. Tinios MIT Plasma Fusion Center.
6P 13 Closed Loop Response of Elongated Plasmas in Alcator C--Mod.
G.
Tinios, S.F. Horne, I.H. Hutchinson, and S.M. Wolfe, MIT Plasma
Fusion Center.
6P 14 A $CO_{2}$ Laser Polarimeter for Measurement of Plasma Current
Profile in Alcator C-Mod.
C.H. Ma, D.P. Hutchinson, R.K. Richards,
ORNL; J. Irby, and T. Luke, MIT Plasma Fusion Center.
6P 15 A $CO_{2}$-Laser Thomson Scattering Ion-Tail Diagnostic for Alcator
C-Mod.
R.K. Richards, D.P. Hutchinson, C. H. Ma, ORNL; and Y.
Takase, MIT Plasma Fusion Center.
6P 16 Gamma-Ray Emissions from the Alcator C-MOD Tokamak.
K.W. Wenzel, D.
A. Pappas, R.D. Petrasso and B.J. Banaszak. MIT Plasma Fusion Center
and Nuclear Engineering Dept.
6P 17 Measurements of Escaping Charged Fusion Products on Alcator C-Mod.
D.H. Lo, R.L. Boivin, and R.D. Petrasso, MIT Plasma Fusion Center.
6P 18 Ion Temperature Measurements using Particle Diagnostics on Alcator
C-Mod.
R.L. Boivin, C.L. Fiore, J.C. Miller and J.C. Rost, MIT
Plasma Fusion Center.
6P 19 X-ray Observations of Helium-like Scandium from the Alcator C-Mod
Tokamak.
J.E. Rice, M.A. Graf, F. Bombardat, J.L. Terry, E.S. Marmar
and K. Giesing, MIT Plasma Fusion Center.
6P 20 Visible Continuum Profile Measurements in Alcator C-Mod.
C.
Christensen, E. Marmar, D. Garnier, M. Graf, M. Greenwald, J. Irby,
T. Luke, J. Rice, J. Schachter, and J. Terry, MIT Plasma Fusion
Center; M. May and M. Finkenthal, Johns Hopkins University.
6P 21 Lithium Pellet Injection Experiments on Alcator C-Mod.
D. Garnier,
E. Marmar, C. Christensen, M. Graf, R. Granetz, A. Hubbard, J. Irby,
C. Kurz, T. Luike, P. O'Shea, J. Snipes, J. Terry, S. Wolfe, MIT
Plasma Fusion Center; B. Welch and H. Griem, U. Of Maryland; M. May
and M. Finkenthal, Johns Hopkins U.
6P 22 Line Shapes of Balmer Series Trallsitions from Alcator C-Mod.
B.L.
Welch, and H. R. Griem, University of Maryland Institute for Plasma
Research; J.l. Terry, C. Kurz, B. Lipschultz, E. Marmar, and G.M.
McCracken, MIT Plasma Fusion Center.
6P 23 Investigation of the Molybdenum Charge State Ionization Balance
using Experimental Spatial Profiles of Mo Emissions from Alcator
C-Mod.
J.L. Terry, M.A. Graf, J.E. Rice, MIT Plasma Fusion Center;
F. Bombarda, ENEA Frascati; M.J. May, M. Finkenthal, The Johns
Hopkins University; K. Fournier, W. Goldstein, LLNL.
6P 24 Molybdenum Radiative Power Losses from ICRF-heated Alcator C-Mod
Plasmas.
M.J. May, M. Finkenthal 1, S.P Regan, H.W Moos, Department
of Physics, The Johns Hopkins University; J.A. Goetz, J.L. Terry,
S. Golovato, M.A. Graf, E.S. Marmar, M. Porkolab, Y. Takase, MIT
Plasma Fusion Center; K.B. Fournier, W. Goldstein, LLNL. 1=Racah
Institute of Physics, Hebrew University, Jerusalem, Israel.
6P 25 Forbidden Lines in the Spectra of MoXV and MoXVI as a Diagnostic for
the Alcator C-Mod Plasma.
K.B. Fournier, W.H. Goldstein, R. Walling,
A. Osterheld, Lawrence Livermore Nat'l Labs; M. May, M. Finkenthal,
Johns Hopkins University; J. Terry, J. Rice, M. Graf, MIT Plasma
Fusion Center.
6P 26 The CMOD Divertor Thomson Scattering System.
D. Johnson, B. Grek,
Princeton Plasma Physics Laboratory; D. Dimock, J. Lowrance,
Princeton Scientific Instruments; B. Lipschultz, R. Watterson, MIT
Plasma Fusion Center.
6P 27 A Numerical Investigation of Detached Radiative Divertor Plasma
Regimes.
M. Petravic, G. Bateman, C.F.F. Karney, D. P. Stotler, and
R. Vesey, Princeton University, Plasma Physics Laboratory.
6P 28 DEGAS Modeling of Alcator C-Mod Divertor Plasmas.
D.P. Stotler, J.
A. Snipes 1, B. Labombard 1, G.M. McCracken 1, and R. Vesey,
Princeton Plasma Physics Laboratory, Princeton University.
6P 29 Capillary Gas Injection Experiments on Alcator C-Mod.
D. Jablonski,
B. Labombard, B. Lipschultz, and G. McCracken. MIT Plasma Fusion
Center.
6P 30 Radiation Emissivities in the Alcator C-Mod Divertor.
J.A. Goetz, R.
S. Granetz, B. Lipschultz, and R. Nachtrieb, MIT Plasma Fusion
Center.
6P 31 Scaling and Transport Analysis of Divertor Conditions on the Alcator
C-Mod Tokamak.
B. Labombard, J. Goetz, D. Jablonski, C. Kurz, B.
Lipschultz, G. McCracken, A. Niemczewski, Alcator Group, MIT Plasma
Fusion Center.
6Q 1 Alpha Ash Transport and Tritium Transport on TFTR.
E.J. Synakowski,
P.C. Efthimion, R.J. Fonck 1, L.C. Johnson, G. McKee 1, B.C.
Stratton, R.E. Bell, R. Budny, C.E. Bush, M. Zarnstorff, Princeton
Plasma Physics Laboratory, Princeton, New Jersey, 08543.
1=University of Wisconsin, Madison.
6Q 2 Microinstability Analysis of TFTR D-T Plasmas.
W.M. Tang and G.
Rewoldt, Princeton University.
6Q 3 Disruption Avoidance on TFTR.
D. Mueller, M.G. Bell, E. Fredrickson
and the TFTR Group, Princeton Plasma Physics Laboratory.
6Q 4 Search for TAE Modes at Low Ion Temperature and High q(0) in TFTR
DT.
K.M. Young, S.J. Zweben, S.H. Batha 1, R.V. Budny, Z. Chang 2,
C.Z. Cheng, D.S.Darrow, E.D. Fredrickson, G.Y. Fu, F.M. Levinnton 1,
D.R. Mikkelsen, G.L. Schmidt, S.D. Scott, D.A. Spong 3, J.D.
Strachan and the TFTR Group, PPPL. 1=Fusion Physics and Technology;
2=University of Wisconsin; 3=ORNL.
6Q 5 Coherent fluctuations in the initial TFTR D-T experiments.
E.
Fredrickson, Z.Y. Chang 1, C.Z. Cheng, J. Dunlap 2, G.Y. Fu, A.
Janos, J. Manickam, E. Mazzucato, K.M. McGuire, R. Nazikian,
Princeton University, Plasma Physics Laboratory. 1=University of
Wisconsin, Madison, wi; 2=Oak Ridge National Laboratory, Oak Ridge,
TN.
6Q 6 Measurements of Internal Coherent MHD activity in TFTR.
S.F. Paul 1,
Z. Chang 2, R.D. Durst 2, and R.J. Fonck 2. 1=Princeton University;
2=University of Wisconsin.
6Q 7 Core Localized Energetic Particle Driven Modes in TFTR.
R. Nazikian,
E. Mazzucato, Z. Chang, E.D. Fredrickson, and H.K. Park, Princeton
Univeristy.
6Q 8 Fishbone Modes in the TFTR D-T Experiments.
H. Hsuan, Z. Chang, E.D.
Fredrickson, R. Budny, D. Darrow, A.Janos, K.M. McGuire, R.
Nazikian, G. Taylor, Z. Zarnstorff, and S. Zweben, Princeton
University, Plasma Physics Laboratory.
6Q 9 Toroidal Alfven Eigenmodes in Supershot Plasmas in TFTR.
K.L. Wong,
Z. Chang, D. Ernst, G.Y. Fu, R. Majeski, E. Mazzucato, R. Nazikian,
J. Rogers, G. Schilling, G. Schmidt, J.R. Wilson, Princeton
University.
6Q 10 Linear Stability Analysis of TAE Mode in TFTR D-T Experiments.
C.Z.
Cheng, G.Y. Fu, R. Budny, E. Fredrickson, K.L. Wong, S.J. Zweben,
and TFTR Group, Princeton University.
6Q 11 Stability and Mode Structure of TAE Modes in ITER and TFTR DT
Plasmas.
J. Candy and M.N. Rosenbluth, Physics Department,
University of California, San Diego, La Jolla, CA 92093-0319; H.L.
Berk, Institute for Fusion Studies, The University of Texas at
Austin, Austin, TX 78712.
6Q 12 Preliminary Measurements of Limiter Heating due to Alpha Particle
Losses during High Fusion Power Deuterium-Tritium Operation of TFTR.
A. Janos, D.K. Owens, D. Darrow, M. Redi, M. Zarnstroff, S. Zweben,
PPPL.
6Q 13 First measurements of tritium recycling in TFTR.
C.H. Skinner, D.P.
Stotler, H. Adler, R.V. Budny, J. Kamperschroer, L.C. Johnson, A.T.
Ramsey, Princeton University.
6Q 14 Impurities in TFTR Deuterium and Tritium Plasmas.
K.W. Hill, H.
Adler, M. Bitter, S. von Goeler, A.T. Ramsey, and W. Tighe,
Princeton University.
6Q 15 ICRF Heating of TFTR D-T Supershot Plasmas.
G. Taylor, J.R. Wilson,
M.G. Bell, R.V. Budny, C.E. Bush 2, Z. Chang 1, D. Darrow, D.R.
Ernst 3, E. Fredrickson, R.C. Goldfinger 2, B. Grek, G. Hammett, A.
Janos, D.W. Johnson, L.C. Johnson, S.S. Medley, R. Majeski, M.
Murakami 2, H. Park, C.K. Phillips, D.A. Rasmussen 2, J.H. Rogers,
G. Schilling, J.D. Strachan, J.E. Stevens, E. Synakowski, and S.
Zweben, Princeton University. 1=Univeristy of Wisconsin, Madison;
2=ORNL, Oak Ridge, Tennessee; 3=MIT, Cambridge, Massachusetts.
6Q 16 Fast Wave Current Drive and ICRF Wave Studies on TFTR.
J.H. Rogers,
R. Majerski, C.K. Phillips, G. Schilling, J. Stevens, J.R. Wilson,
Princeton University; G. Hanson, M. Murakami, Oak Ridge National
Laboratory; and Y.L. Ho, SAIC.
6Q 17 Mode conversion electron heating and current drive in TFTR.
R.
Majeski, J.C. Hosea, C.K. Phillips, J.H. Rogers, G. Schilling, J.E.
Stevens, J.R. Wilson, N.J. Fisch, E.J. Valeo, and the TFTR Group,
PPPL; M. Murakami, D. Rasmussen, ORNL.
6Q 18 Operation of the TFTR ICRF Heating System in the D-T Phase.
G.
Schilling, J.C. Hosea, R. Majeski, J.H. Rogers, J.E. Stevens, J.R.
Wilson, Princeton University; and D.A. Rasmussen, Oak Ridge National
Laboratory.
6Q 19 Reflectometer Measurements of Edge-Density Profiles at an ICRF
Antenna on TFTR.
A.C. England, J.B. Wilgen, G.R. Hanson, D.A.
Rasmussen, M. Murakami, D.C. Stallings 1, J.H. Rogers 2, J.R. Wilson
2, ORNL. 1=Computing Applications Division, Martin Marietta Energy
Systems, Inc.; 2=Princeton Plasma Physics Laboratory, Princeton, NJ,
08543-0451.
6Q 20 Identification of Multiple Propagating Hot-Plasma Modes for High
$k_{\parallel}$.
D.W. Ignat, M. Ono, R.P. Majeski, C.K. Phillips,
and J.R. Wilson, Princeton University.
6Q 21 X-ray Spectra from RF-heated Tokamak Fusion Test Reactor (TFTR)
Plasmas.
M. Bitter, H. Hsuan, K.W. Hill, R. Majeski, C.K. Phillips,
J. Rogers, G. Schilling, J.R. Wilson, Princeton University.
6Q 22 TRANSP Modeling of the Effect of Sawteeth on ICRF Power Deposition
in TFTR.
R.C. Goldfinger, D.B. Batchelor, M. Murakami, Oak Ridge
National Laboratory, Oak Ridge, TN 37831-8058; C.K. Phillips, R.
Budny, G.W. Hammett, D.M. McCune, J.R. Wilson, M.C. Zarnstorff, and
the TFTR Team, Princeton Plasma Physics Laboratory, Princeton, NJ
08543.
6Q 23 Loss of MeV Ions in TFTR Due to Coherent MHD Modes.
K. Tobita 1, S.
Zweben, D. Darrow, H. Herrmann, Z. Chang 2, Princeton Plasma Physics
Laboratory. 1=Japan Atomic Energy Res. Inst.; 2=University of
Wisconsin.
6Q 24 Use of Major Radius Shifts to Examine Confined Alphas Near the
Passing/Trapped Boundary in TFTR.
H.W. Herrmann, D.S. Darrow, H.E.
Mynick, M.C. Zarnstorff, S.J. Zweben, and the TFTR Group, Princeton
University.
6Q 25 D-T Results of TFTR's Alpha Collector Probe.
G.P. Chong, A.A. Haaz,
C.S. Pitcher, Univeristy of Toronto; H.W. Herrmann, D.S. Darrow, J.
T. Timberlake, S.J. Zweben, and the TFTR Group, Princeton
University; R.G. Macaulay-Newcombe, McMaster University.
6Q 26 Electron Temperature and Density Profiles in TFTR Tritium, Deuterium
and Helium Discharges.
B. Grek, B. LeBlamc, A. Ramsey, D. Johnson,
G. Taylor, H. Park, Princeton Plasma Physics Laboratory.
6Q 27 Observations of ICE in D-T Plasmas on TFTR.
S. Cauffman and R.
Majeski, Princeton University.
6Q 28 Ion Cyclotron emission (ICE) due to the newly-born fusion products
induced fast Alfven wave radiative instabilities in tokamaks.
V.
Arunasalam, R. Majeski, and S. Cauffman, Princeton University.
6Q 29 Excitation of Alfven Cyclotron Instability by Charged Fusion
Products in Tokamaks.
N.N. Gorelenkov, C.Z. Cheng, S. Cauffman, and
R. Majeski, PPPL.
6Q 30 A Mechanism for Beam-Driven Excitatin of Ion Cyclotron Harmonic
Waves in TFTR.
R.O. Dendy 1, K.G. McClements 1, C.N. Lashmore-Davies
1, R. Majeski 2, and S. Cauffman 2. 1=UKAEA Government Division,
Culham, UK; 2=Princeton Plasma Physics Laboratory.
6Q 31 Differentiating among parallel electric resistivity models using
internal measurements in TFTR.
S.H. Batha, F.M. Levinton, Fusion
Phyiscs & Technology, Inc., and M.C. Zarnstorff, Princeton Plasma
Physics Laboratory.
6Q 32 Isotopic Mass Scaling in TFTR Discharges.
R.V. Budny, and the TFTR
group, PPPL, Princeton University, Princeton, NJ.
6Q 33 Momentum Transport and Velocity Gradient Driven Modes in TFTR
Plasmas.
D.R. Ernst 1, B. Coppi 1, S.D. Scott, and the TFTR Group,
Princeton Plasma Physics Laboratory. 1=also at Massachusetts
Institute of Technology, Cambridge, MA 02139.
6Q 34 Theory-Based Transport Simulations of TFTR Supershots.
Glenn
Bateman, Jan Weiland 1, Hans Nordman 1, Jon Kinsey 2, Clifford
Singer 2, and R.V. Budny, Princeton University, Plasma Physics
Laboratory. 1=Chalmers University of Technology, Goteborg, Sweden;
2-University of Illinois, Urbana, IL 61801-2984.
6Q 35 The Use of Optical Fibers on the Next Generation Tokamaks.
A.T.
Ramsey, H.G. Adler, W. Tighe, Princeton University.
6Q 36 Luminescence and Transmission Measurements on Fibers Exposed to High
Radiation Fluxes - Dependence on Diameter and Material.
H.G. Adler,
D. Griscom 1, K.W. Hill, P. Morgan 2, A.T. Ramsey, and W. Tighe,
Princeton University. 1=Naval Research Laboratory, Washington, DC,
USA; 2=JET Joint Undertaking, Abingdon, UK.
6Q 37 Studies of Transmission in Heated Optical Fibers during D-T
Discharges.
W. Tighe, A. Ramsey, P. Morgan 1, H. Adler, D. Cylinder,
D. Griscom 2, D. Johnson, and R. Palladino, Princeton University.
6R 1 TFTR Experiments with 2% Tritiium Fueling.
D.L. Jassby, J.D.
Strachan, M.G. Bell, R.V. Budny, P.C. Efthimoin, L.R. Grisham, L.C.
Johnson, S.J. Zweben, and the TFTR Group, Princeton Plasma Physics
Lab.
6R 2 Trace Tritium Measurements Using the TFTR Collimated Helium
Detectors.
J.D. Strachan and TFTR Group, PPPL, Princeton University,
Princeton, NJ.
6R 3 Neutron Emissin Profiles Measured in the Current Mode with the
Multichannel Collimator on TFTR.
A.L. Roquemore, S. von Goeler, L.C.
Johnson, Princeton Plasma Physics Laboratory.
6R 4 Tritium Transport Studies in TFTR.
L.C. Johnson and TFTR Group,
PPPL, Princeton University, Princeton, NJ.
6R 5 Modelling of the DT Neutron Rate and Recycling in TFTR.
S.E. Kruger
1, R.V. Budny, J.D. Strachan, C.H. Skinner, Z. Chang 1, J.D. Callen
1, L.C. Johnson, D.L. Jassby, and TFTR Team, Princeton University.
6R 6 Role of the Neutral Beam Fueling Profile in Energy Confinement and
Neutron Emissin in DT Plasmas.
H. Park, M.G. Bell, R.V. Budny, C.E.
Bush 1, D. McCune, S.A. Sabbagh 2, G. Taylor, W. Tang, M. Yamada, R.
M. Wieland, Princeton University. 1=ORNL, Oak Ridge, Tennessee;
2=Columbia Univ, New York, NY.
6R 7 The Effect of MHD Activity on the Temporal Evolution of the Radial
Neutron Emission Profiles from the Multichannel Collimator on TFTR.
S. von Goeler, A.L. Roquemore, E. Fredrickson, L.C. Johnson,
Princeton University, Plasma Physics Laboratory.
6R 8 Experimental Measurement of Nonlinear Energy Transfer in the Core of
TFTR.
J.S. Kim 1, R.D. Durst 1, R.j. Fonck 1, S.F. Paul 2.
1=University of Wisconsin-Madison; 2=Princeton University.
6R 9 Ion Temperature and Parallel Velocity Fluctuation Measurements on
TFTR.
H.T. Evensen, R.D. Durst, R.J. Fonck, S.F. Paul 1, and M.C.
Zarnstorff 2, University of Wisconsin-Madison. 1-Princeton
University.
6R 10 Refined Transient Electron Heat Diffusivity results From TFTR.
M.W.
Kissick 1, E.D. Fredrickson, J.D. Callen 1, Princeton Plasma Physics
Lab. 1=University of Wisconsin-Madison.
6R 11 Modeling of Background Electron Impact Excited Emission for Ion
Temperature Measuremeents in TFTR.
R.E. Bell, E.J. Synakowski, C.E.
Bush.
6R 12 An analysis of TFTR kinetic data set consistency.
B. LeBlanc, B.
Grek, H. Park, S. Scott, G. Taylor, and the TFTR group, Princeton
Plasma Physics Laboratory.
6R 13 Experimental Observation of Negative Magnetic Shear in TFTR and its
Effect on Transport.
F.M. Levinton and S.H. Batha, Fusion Physics &
Technology, 3547 Voyager St., Torrance, CA 90503; R. Budny, J.
Manickam, G. Rewoldt, G. Schmidt, and M.C. Zarnstroff, Princeton
Plasma Physics Laboratory; S. Sabbagh, Columbia University.
6R 14 Approach for Production of Enhanced Negative Shear Region in PEP
Mode Discharges at High Ip.
G.L. Schmidt, L. Baylor 1, E.
Fredrickson, G. Hammett, A. Janos, F.M. Levinton 2, H.K. Park, J.R.
Wilson, M.C. Zarnstorff, Princeton University. 1=ORNL; 2=Fusion
Physics & Technologies.
6R 15 Measurements of the Fast Confined Alphas in TFTR Using Pellet Charge
Exchange.
H.H. Duong, R.K. Fisher, D.K. Mansfield 1, J.M. McChesney,
S.S. Medley 1, P.B. Parks, M.P. Petrov 2, A.L. Roquemore 1, General
Atomics. 1=Princeton Plasma Physics Laboratory, Princeton, NJ; 2=AF
Ioffe Physical-Technical Institute, St. Petersburg, Russia.
6R 16 $\alpha$-CHERS Measurements of D-T Fusion $\alpha$'s in TFTR.
G.
McKee 1, R. Budny 2, R.J. Fonck 1, and B. Stratton 2. 1=University
of Wisconsin-Madison; 2=Princeton University.
6R 17 Performance of the $\alpha$-CHERS Diagnostic on TFTR.
B.C. Stratton,
R. Budny, R.J. Fonck 1, G. McKee 1, and T. Thorson 1, Princeton
University. 1=University of Wisconsin-Madison.
6R 18 A 1kW, 60 GHz Collective Thomson Scattering Diagnostic for Alpha
Particles in TFTR.
J.S. Machuzak, P.P. Woskov, and J. Gilmore, MIT
Plasma Fusion Center; N. Bretz and D.A. Russell, Lodestar Research
Corp.; and H. Bindslev, JET.
6R 19 Stochastic Ripple Transport of Fast Ions: TRANSP Simulations of
TFTR.
M.H. Redi, M.C. Zarnstorff, D.C. McCune, J. Schivell, R.B.
White, R.J. Goldston, Princeton University.
6R 20 Asymmetry Modifications to the TRANSP Monte Carlo Fast Ion Code.
D.C. McCune, R.J. Goldston, R.T. McCann, R.M. Wieland, T.B.
Terpstra, Princeton University; B. Balet and P. Stubberfield, JET.
6R 21 Up-Down Asymmetry Modifications to the Flux Surface Geometry in
TRANSP.
R.M. Wieland, D.C. McCune, T.B. Terpstra, Princeton
University; B. Balet, P. Stubberfield, JET Joint Undertaking; and S.
P. Hirshman, Oak Ridge National Laboratory.
6R 22 Fusion Product Ions and Time Step Control in TRANSP.
J. Schivell,
D.C. McCune, R.J. Goldston, M.H. Redi, Princeton University.
6R 23 Lithium Pellet Injection Upgrade to the TRANSP Monte Carlo Fast Ion
Code.
T.B. Terpstra, D.C. McCune, Princeton University.
6R 24 Comparison of Predicted and Measured Temperatures in TFTR
Dimensionless Scaling Experiments.
D.R. Mikkelsen, S.D. Scott, H.G.
Adler, M.A. Beer, M.G. Bell, C.E. Bush, W. Dorland 1, B. Grek, G.W.
Hammett, K.W. Hill, D.W. Johnson, M. Kotschenreuther 1, D.K.
Mansfield, H.K. Park, J. Schivell, E.J. Synakowski, G. Taylor,
Princeton University. 1=IFS, U. Texas.
6R 25 Temperature and toroidal velocity of impurities in TFTR.
D.H.
McNeill, 121 Webster Ave., Jersey City, NJ 07307.
6R 26 Study of Magnetic Island Structures in TFTR.
C. Ren, J.D. Callen, Z.
Chang, E.D. Fredrickson 1, S. Paul 1, A. Janos 1, K.M. McGuire 1,
and M. Zarnstorff 1, University of Wisconsin-Madison. 1=Princeton
University.
6R 27 Studies of the Diffusion of Tritium Beam Ions at TFTR.
E. Ruskov,
W.W. Heidbrink, University of California, Irvine; R. Budny,
Princeton University.
6R 28 Disruptions during Discharge Ramp-down Period in TFTR Tokamak.
H.
Takahashi, E. Fredrickson, and K. McGuire, Princeton University.
6R 29 Midplane Density Measurements.
F.C. Jobes, Princeton Plasma Physics
Laboratory, Princeton, NJ 08543.
6R 30 TFTR Neutronics and Shielding Efficiency Measurements During D-T
Operations.
H.W. Kugel, G. Ascione, M. Bitter, S. Elwood, J.
Gilbert, L.-P. Ku, J. Levine, A.L. Roquemore, S. Sesnic, and K.
Rule, Princeton University; N. Azziz, P. Goldhagen, F. Hajnal, and
P. Shebell, US DOE EML; C.W. Barnes, LANL; A. Kumar, and M.A. Abdou,
UCLA.
6S 1 Non-LTE Ion COnfiguration Probability from the Average Ion Model.
Wenbing Pei, and Tieqiang Chang, Institute of Applied Physics and
Computational Mathematice, PO Box 8009, Beijing 100088, P.R. China.
6S 2 Radiation Hydrodynamics Of A Double Pulse Laser Driven Al/Ar
Microballoon.
R. Clark, J. Davis, J. Giuliani, and P. Kepple. Plasma
Physics Division, Naval Research Lab., Washington, DC. 20375.
6S 3 Radiating Plasma Structures in Ablating LAser Produced Plasmas.
M.
Klapisch, Artep, Inc.; J.P. Dahlburg, J.H. Gardner, A.J. Schmitt,
Naval Research Laboratory; and A. Bar-Shalom, Nuclear Research
Center, Negev, Israel.
6S 4 Radiative Transport in Slab Geometry.
D.A. Garren, Science
Applications International Corporation; M. Klapisch, ARTEP, Inc.;
J. Gardner, D. Colombant, Naval Research Laboratory.
6S 5 Spectral Line Shape Analysis for Emission and Adsorption Spectra
from Laboratory Plasmas.
P. Wang, J.J. MacFarlane, and G.A. Moses,
University of Wisconsin-Madison.
6S 6 Comparative Assessment Study of Aboveground Soft X-Ray Technology.
M.A. Sweeney, Sandia National Laboratories.
6S 7 JANUS-A New 1D Implosion Code.
D.G. Colombant and A.J. Schmitt,
Plasma Physics Division, Naval Research Laboratory.
6S 8 Comparisons of Hydrocodes for ICF Calculations.
Andrew J. Schmitt,
Denis Colombant, Plasma Physics Division; Jill P. Dahlburg, and John
H. Gardner, LCP&FD, Naval Research Laboratory.
6S 9 Modeling of Smoothing of Nonuniform Pressure in Ablative Plasmas
for Laser Fusion.
Y. Shimuta, K. Nishihara, Institute of Laser
Engineering, Osaka University.
6S 10 Start-up Problem in Laser Fusion -- Perturbation Growth Before the
First-Shock Breakout.
K. Mima, H. Azechi, A. Nishiguchi 1, T. Endo,
and S. Nakai, ILE Osaka Univ. 1=Osaka Institute of Technology.
6S 11 Numerical Simulations of 3D Ablative Hydrodynamic Instability
Experiments.
M.M. Marinak, R.E. Tipton, B.A. Remington, S.V. Weber,
Lawrence Livermore National Laboratory.
6S 12 Dynamical Behavior and Chaos in Hydrodynamic Instabilities and
Evaporation Processes.
T. Yabe, Gunma Iniversity, Kiryu, Gunma 376,
Japan.
6S 13 Rayleigh-Taylor instability of ablation fronts.
A.R. Piriz 1, and J.
G. Wouchuk 2, Associazione Euratom-ENEA, C.P. 65, 00044 Frascati,
Rome, Italy. 1=On leave from Consesjo Nacional de Incestigaciones
Cientificas y Tecnicas (CONICET), Argentina; 2-Fellow of CONICET,
Argentina.
6S 14 Scaling Laws for Non-Conventional Hohlraums.
Mordecai D. Rosen,
Lawrence Livermore National Laboratory.
6S 15 Numerical study of Mega Joule hohlraum filled with plastic foam.
S.
Laffite, J.M. Dufour, Centre d'etudes Limeil Valenton.
6S 16 Physics and Design of Radiation-Driven Targets for Heavy Ion Fusion.
Darwin D.-M. Ho and Max Tabak, Lawrence Livermore National
Laboratory.
6S 17 Implosion Designs for Fast Ignitor Experiments on Nova.
S.P.
Hatchett, J.H. Hammer, M. Tabak, S.C. Wilks, J.G. Woodworth,
Lawrence Livermore National Laboratory.
6S 18 Scaling laws for the thermonuclear gain of indirectly laser driven
ICF targets.
D. Juraszek, C. Bayer, CEA/Centre d'etudes de Limeil-
Valenton, 94195 Villeneuve Saint Georges, Cedex, France.
6S 19 Computer Simulations of the Debris and Radiation Emission from an
Ignited NIF Target.
R.R. Peterson, K. Simmons, J.J. MacFarlane, P.
Wang, and G.A. Moses, University of Wisconsin-Madison.
6S 20 X-ray flux symmetry control in advanced Nova hohlraums.
T.J. Murphy
and P. Amendt, Lawrence Livermore National Laboratory.
6S 21 Nova hohlraum time-dependent drive asymmetry from witness balls.
P.
Amendt, S.G. Glendenning, B.A. Hammel, R.G. Hay, and L.J. Suter,
Lawrence Livermore National Laboratory.
6S 22 The Use of Thin-Wall Imaging for ICF Experiments.
J.M. Wallace, D.A.
Baker, N.D. Delamater, E.LK. Lindman, and J.A. Phillips, Los Alamos
National Laboratory, Los Alamos, NM 87544.
6S 23 Basic Image Analysis for Nova Symmetry Experiments.
R.G. Hockaday,
N.D. Delamater, D.B. Harris, A.A. Hauer, W.W. Hsing, G.D. Pollak, J.
Oertel, R. Pasha 1, and B. Failor 2, Los Alamos National Laboratory.
1=Lawrence Livermore National Laboratory; 2=Physics International,
San Leandro, CA.
6S 24 Measurements of implosion symmetry using a neutron coded-aperture
microscope.
R.J. Ellis, D. Ress, R.A. Lerche, J.A. Hatch, and L.J.
Suter, Lawrence Livermore National Laboratory, Livermore, CA 94551-
5508.
6S 25 Nova High Growth Factor Implosion Experiments: Modeling and
Analysis.
C.J. Keane, O.L Landen, B.A. Hamel, T.R. Dittrich, S.H.
Langer, and D.H. Munro, Lawrence Livermore National Laboratory.
6S 26 High Growth-Factor ICF Implosions.
O.L. Landen, B.A. Hammel, C.J.
Keane, T.J. Murphy, R.G. Hay, R.A. Lerche, M.B. Nelson, M.D. Cable,
J.D. Kilkenny, T.R. Dittrich, W.K. Levedahl, L. Suter, S.W. Haan, S.
P. Hatchett, R. MacEachern, R. Cook, and R.J. Wallace, LLNL,
Livermore, CA 94550.
6S 27 Fusion Reaction Rates Measured for Nova ICF Targets.
R.A. Lerche,
Lawrence Livermore National Laboratory.
6S 28 RadChem Shell Compression Measurements of Hohlraum Implosions at
Nova.
Michael B. Nelson and Stephen M. Lane, Lawrence Livermore
National Laboratory, Livermore, CA 94550.
6S 29 Relation of Primary- to Secondary-Reaction Products to the Final
Core Parameters of Pure Deuterium Targets in Laser Fusion
Experiments.
S. Cremer, J.P. Knauer, R.L. Kremens, M.A. Russotto, D.
Shvarts, S. Skupsky, and C.P. Verdon, LLE, U. of Rochester.
6S 30 Simulation of 'Saturated' Operation of the MEDUSA Neutron Detector
Array.
R.L. Kremens, M.A. Russotto, and S. Tudman, LLE, U. of
Rochester.
6S 31 A Charged Particle Spectrometer For $\rho R$ Measurements.
D. Hicks,
C.K. Li, R.D. Petrasso, K.W. Wenzel, MIT Plasma Fusion Center; J.P.
Knauer, LLE, Univ. of Rochester.
6S 32 Magnetic Fields Measurements in Dense Plasmas.
A.A. Rupasov, G.S.
Sarkisov, P.N. Lebedev Physics Institute, Moscow, Russia; Yu.S.
Kas'yanov, Institute of General Physics, Moscow, Russia; A.S.
Shianov 1, V. Stefan, Tesla Laboratories, Inc., La Jolla, CA.
1=Permanent address: P.N. Lebedev Physics Institute, Russian Academy
of Science, Moscow, Russia.
6S 33 SDOSS: a Spatially Discriminating, Optical Streaked Spectrograph.
J. Jimerson, J. Cobble, S. Evans, C. Gomez, J. Oertel, Los Alamos
National Laboratory.
6S 34 Time-Dependent Collisional-Radiative Modeling for Analyzing Spectra
Obtained in Light Ion Fusion Experiments.
H.K. Chung, J.J.
MacFarlane, G.A. Moses, and P. Wanf, Fusion Technology Institute,
University of Wisconsin.
6S 35 Monochromatic X-ray imaging diagnostic for argon filled microballoon
imploded at Phebus.
C. Reverdin, J.L. Bourgade, O. Cabourdin, D.
Gilles, D. Juraszek, O. Peyrusse, A. Richard, R. Sauneuf, D.
Schirmann, Centre d'etudes de Limeil-Valenton, 94195 Villeneuve-
Saint-Georges, Cedex, France; L. Beck, A. Rouyer, Centre d'etudes de
Bruyeres-le-Chatel, 91680 Bruyeres-le-Chatel, B.P. 12, France.
6S 36 A Monochromatic two channels microscope for colliding plasma
experiments on Octal-Heliotrope.
J.P. Le Breton, D. Gontier, T.
Jalinaud, D. Juraszek, A. Mens, D. Tersigny, CEA-Centre d'etudes de
Limeil-Valenton, 94195 Villeneuve-Saint-Georges, Cedex, France; I.
Uschmann, M. Vollbrecht, E. Forster, Max-Plank-Working Groupe for
X-ray Optics at the Jena University, Germany.
6S 37 Monochromatic X-ray imaging of Laser-Fusion Targets.
F.J. Marshall,
LLE, U. of Rochester; A. Hauer, J. Oertel, and R. Watt, Los Alamos
National Laboratory.
6S 38 BV, CVI and NVII Lyman Line Profiles from 10 PS KrF-Laser Produced
Plasmas.
Y. Leng, B.L. Welch, J. Goldhaar, and H.R. Griem, Univ. of
Maryland; and R.W. Lee, LLNL.
6T 1 Chaos in a Multipolar Argon Plasma.
C. Arnas-Capeau, M. Carrere, F.
Doveil and R.A. Stern 1, Turbulence Plsama, I.M.T., F-13451
Marseille, France. 1=U. of Colorado, Boulder, CO 80309.
6T 2 A Solenoidal and Monocusp Ion Source (SAMIS).
E.J.T. Burns, J.P.
Brainard, and C.H. Draper, Sandia National Laboratories.
6T 3 A production mechanism of negative hydrogen ions in Uramoto-type
sheet-plasma at Kyoto.
K. Jimbo, Institute of Atomic Energy, Kyoto
University; M. Iima, Plasma Physics Laboratory, Kyoto Uiversity,
6T 4 A simple design for an inexpensive, intermediate size BaO coated
cathode.
H. Pfister, N. Wolf, B. Motter and C. Boswell, Department
of Physics and Astronomy, Dickinson College, Carlisle, PA 17013.
6T 5 An Interferometric Simulation of Density Gradient Effects in the
Capillary Discharge Plasma with a Slotted Open Geometry.
N.S.
Edison, R.W. Lee, P.E. Young, Lawrence Livermore National
Laboratory.
6T 6 Operation of a large hollow cathode discharge.
S.A. Cohen, Plasma
Physics Laboratory, Princeton University, Princeton, NJ 08543.
6T 7 An Air Plasma.
Weng Lock Kang, Mark Rader and Igor Alexeff, ECE;
The University of Tennessee, Knoxville, 37996-2100.
6T 8 Medium-Z Ion SOurce for HIgh Energy Ion Implanation.
L. Bromberg,
MIT Plasma Fusion Center, and M. Tekula, MRAT.
6T 9 Development of a fast modulated high energy diagnostic neutral beam
for TdeV.
Sarkissian A.H. 1 2, Charette E. 1 2, Larose D. 2, and NB
Team. 1=INRS-Energie et Materiaux, U. of Quebec; 2=CCFM, Varennes,
Quebec, Canada.
6T 10 Optimization of Magnetic Nozzles for Coaxial Plasma Accelerators For
Space Propulsion and Environmentally Conscious Manufacturing.
R.P.
Hoyt, J.T. Scheuer, K.F. Schoenberg, R.A. Gerwin, R.W. Moses, H.P.
Wagner, Los Alamos National Laboratory.
6T 11 Coaxial Plasma Accelerators Modeled for Optimum Performance.
R.W.
Moses, R.A. Gerwin, R.P. Hoyt, J.T. Scheuer, and K.F. Schoenberg,
Los Alamos National Laboratory, Los Alamos, NM 87545.
6T 12 Conduction of a high current by a plasma between two conductors.
A.
Fruchtman, Department of Particle Physics, Weizmann Institute of
Science, Rehovot 76100, Israel.
6T 13 High Impedance Plasma Opening Switches.
R.J. Mason, Los Alamos
National Laboratory.
6T 14 Experimental MHD Snowplow in a POS.
G.G. Spanjers, E.J. Yadlowsky,
R.C. Hazelton, J.J. Moschella, HY-TEch Research Corporation, 104
Centre Ct., Radford, VA 14241.
6T 15 Spectroscopic diagnostic of the plasma opening switch an ACE 4.
D.
Wroblewski, J. Thompson, P. Melcher, Maxwell Laboratories, Inc.
6T 16 Magnetic field measurements in a nanosecond Plasma Opening Switch.
R. Shpitalnik, R. Arad, A. Fruchtman, Ya.E. Krasik, M. Sarfaty, A.
Weingarten, and Y. Maron, Weizmann Institute of Science, Rehovot,
Israel.
6T 17 Electric field measurements in an nansecond Plasma Opening Switch.
A. Weingarten, S. Alexiou, M. Sarfaty, Ya. Krasik, R. Arad and Y.
Maron, Weizmann Institute of Science, Rehovot, 76100 Israel.
6T 18 Plasma Opening Switch Using Laser-Produced Plasma.
H. Akiyama, U.
Katschinski, S. Ihara 1, S. Katsuki, and S. Maeda, Kumamoto
University, Kumamoto 860, Japan. 1=Saga University, Saga, Japan.
6T 19 Repetitive Operation of High Voltage Pulse Power System.
K.
Masugata, H. Maekawa, K. Yatsui, Nagaoka Univ. Tech., Japan.
6T 20 Results from High Current Plasma Z-Pinch and Vacuum Switching
Experiments.
J.H. Goforth, H. Oona, M.L. Yapuncich, W.D. Zerwekh, E.
A. Lopez, J.S. Shlachter, F.J. Wysocki, J.L. Stokes, L.R. Veeser, G.
Idzorek, A.E. Greene, W.E. Anderson, and R.E. Reinovsky, Los Alamos
National Laboratory.
6T 21 Increased X-ray Yield by Mixing Near-Z Elements on High Current Z-
Pinches.
C. Deeny, P.D. Lepell, B.H. Failor, J. Meachum and S.L.
Wong, Physics International Company; J.P. Apruzese, K.G. Whitney,
J.W. Thornhill, and J. David, Plasma Physics Division, Naval
Research Laboratory.
6T 22 Two-Dimensional Simulations of Foil Implosion Radiation Experiments
on the Los Alamos Pegasus II and Procyon Systems.
D.L. Peterson, R.
L. Bowers, and W. Matuska, Los Alamos National Laboratory.
6T 23 Experimental and Computational Results of PROCYON Switched Implosion
Foil Experiments.
G.T. Nakafuji, R.L. Bowers, D.L. Peterson, and N.
F. Roderick, Los Alamos National Laboratory.
6T 24 Experimental Study of Frequency Shift of an Electromagnetic Wave
Propagating Through a Rapidly Created periodic Plasma.
James Faith,
S.P. Kuo, Joe Sun, and Joe Huang, Weber Research Institute,
Polytechnic University, Route 110, Farmingdale, NY 11735.
6T 25 Simulation Study on Electromagnetic Frequency Shift in Rapidly
Created and Periodically Structurally Plasma.
Joe Sun, Joe Huang,
S.P. Kuo, and James Faith, Weber Research Institute, Polytechnic
University, Route 110, Farmingdale, NY 11735.
6T 26 Plasma Formation on Electrodes of a High Voltage Diode.
F.
Schwirzke, M.O. Callahan, X.K. Maruyama, C.M. Wright, Naval
Postgraduate School.