1RV 1 Review of Deuterium-Tritium Experiments on TFTR.
K.M. McGuire
Princeton Plasma Physics Laboratory.
1IA 1 Steady-state Improved Confinement Studies in the JT-60 Tokamak.
T. Fukuda, Japan Atomic Energy Research Institute, Japan.
1IA 2 The New Phase of JET and Prospects for Future Operation.
B.J.D.
Tubbing and JET Team, JET Joint Undertaking, United Kingdom.
1IB 1 Spectroscopic Investigation of Fast (ns) Magnetic Field
Penetration in a Plasma.
Y. Maron, The Weizmann Institute of
Science, Israel.
1IB 2 Diagnostics of fast-ion minority in tokamak plasmas using
collective scattering from self-excited eigenmodes.
A.D.Piliya,
A.F. Ioffe Institute, Russia.
1IB 3 Use of a Plasma Mirror as a High Frequency Microwave Beam
Director.
R.A. MEGER, Naval Research Laboratory.
1E 1 Stimulated Raman Scattering of Short Laser Pulses.
C.J. McKinstrie,
R. Betti, R.E. Giacone, and T. Kolber, LLE, U. of Rochester.
1E 2 Observation of Forward Raman Scattering and Energetic Electrons in
High Intensity, Sub-Picosecond Laser, Underdense Gas-Target
Experiments.
C.A. Coverdale, C.B. Darrow, M.D. Perry, Lawrence
Livermore National Lab, P.O. Box 808, Livermore, CA 94550; W.B.
Mori, C. Decker, K.C. Tzeng, C. Joshi, C. Clayton, Departments of
Physics and Electrical Engineering, University of California, Los
Angeles, Los Angeles, CA 90024.
1E 3 Spectrally Modulated Stimulated Raman and Anomalous Backscatter in
High-Intensity, Sub-Picosecond Laser, Underdense Gas-Target
Experiments.
C.B. Darrow, C.A. Coverdale, J.K. Crane, and M.D.
Perry, Lawrence Livermore National Laboratory, Box 808, Livermore CA
94550; W.B. Mori, C. Decker, C. Joshi, and C. Clayton, Departments
of Physics and Electrical Engineering, University of California at
Los Angeles, Los Angeles, CA 90024-1547; G. Shvets, Massachusetts
Institute of Technology.
1E 4 Absorption and Emission Studies of Solid Targets Heated by Ultra-
short Pulse Lasers.
R S. Walling, W.E. Alley, J. Dunn, M.E. Foord,
D.M. Gold, W.H. Goldstein, G. Guethlein, R.M. More, A.L. Osterheld,
D.F. Price, P.W. Rambo, H.A. Scott, R.E. Stewart, R. Shepherd,
B.K.F. Young, Lawrence Livermore National Laboratory.
1E 5 MeV plasma production from high intensity, picosecond laser plasmas.
A.P. Fews l, F.N. Beg 2, A.R. Bell 2, A.E. Dangor 2, C.B. Darrow 3,
M. Glinsky 3, B.A. Hammel 3, M. Holden 4, P. Lee 2, P.A. Norreys 5,
M. Tafarakis 2, G.J. Tallents 4. 1=Department of Physics,
University of Bristol, Royal Fort, Tyndall Ave., Bristol BS8 1TL,
UK; 2=Imperial College of Science Technology and Medicine, Prince
Consort Road, London SW7 2AZ, UK; 3=Lawrence Livermore National
Laboratory, Livermore, CA 94550, USA; 4=Department of Physics,
University of Essex, Wivenhoe Park, Colchester C04 3SQ, UK;
5=Central Laser Facility, Rutherford Appleton Laboratory, Chilton,
Didcot, Oxon, OX11 OOX. UK.
1E 6 Picosecond Laser-Plasmas in Microstructured Targets.
R.S.
Marjoribanks, G. Kulcsar, F.W. Budnik, L. Zhao, Dept. of Physics;
P.R. Herman, Dept. of Electrical and Computer Engineering; D.
Al-Mawlawi, M.Moskovits, Dept. of Chemistrv, Univ. of Toronto and
OLLRC.
1E 7 Intense, Ultrashort Laser Pulse Propagation Through Aluminum Vapor.
P.R. Bolton, B.M. Penetrante, A.B. Ritchie, and R.E. Stewart,
Lawrence Livermore National Laboratory.
1E 8 Stability, Propagation and Applications of Ultra Intense Short Laser
Pulses in Plasmas.
P. Sprangle, E. Esarey, and J. Krall, Plasma
Physics Division, Naval Research Laboratory.
1E 9 Relativistic Self-Focusing and Channel Formation in Laser-Plasma
Interactions.
Burke Ritchie, Lawrence Livermore National Laboratory.
1E 10 Trident Short Pulse Laser.
J. Cobbie, R. Gibson, R. Johnson 1, K.
Moncur 1, R. Watt, Los Alamos National Laboratory. 1=University of
Michigan.
1E 11 Classical to Quantum Mechanical Transition in Laser-Plasma
Interactions.
B.W. Boreham 1, H. Hora 2 and D.S. Newman 1. 1=Central
Queensland University, QLD 4702 Australia; 2=University of New South
Wales, NSW 2033, Australia.
1E 12 Correspondence Principle of Electromagnetic Interaction.
H. Hora l
and B.W. Boreham 2. 1=University of New South Wales, Kensington,
2033, Australia; 2=Central Queensland University, Rockhampton,4700,
Australia.
1F 1 Alfven Wave Interactions with the Auroral Ionosphere.
R.L. Lysak,
School of Physics and Astronomy. University of Minnesota.
1F 2 Wave-Particle Interactions of Alfen Waves in the Auroral Zone.
B.
Thompson, R.L. Lysak, Universitv of Minnesota School of Physics and
Astronomy.
1F 3 Two-timescale theories of turbulence in the auroral magnetosphere.
K.Y. Sanbonmatsu, M.V. Goldman, and D.L. Newman, APAS Dept.
University of Colorado, Boulder.
1F 4 Generation of Nonsinusoidal Electromagnetic Impulse by Particle
Bunch in the Double Layer.
V.I.Maslov, NSC Kharkov Institute of
Physics and Technology, Kharkov 310108, Ukraine.
1F 5 Communication through the plasma sheath.
S.Nazarenko 1, A.Newell 1,
A. Rubenchik 2. 1=Department of Mathematics, University of Arizona,
Tucson,AZ 85721; 2=PPRI,UC Davis and LLNL, Livermore, Ca 94550.
1F 6 Laboratory High-Energy Astrophysics on Lasers.
W.H. Goldstein, D.A.
Liedahl, R.S. Walling, M.E. Foord, A.L. Osterheld, and B.G. Wilson,
Lawrence Livermore National Laboratory.
1F 7 Meson production Cross Sections for proton-proton interactions in
the interstellar medium.
J.P. Schneider, J.W. Norbury, University of
Wisconsin-La Crosse.
1F 8 Astrophysical Jets as Simulated by a 3-D Electromagnetic Particle
Code.
K.-I. Nishikawa, R.L. Mutel, University of Iowa, J.-I. Sakai,
Toyama University; G.A. Benford, University of California Irvine.
1F 9 Meson Regge Trajectories.
M.L. Pruse, J.W. Norbury, University of
Wisconsin-La Crosse; K. Maung Maung, Hampton University.
1P 1 Diagonalization and Canonization of the Linearized Maxwell-Vlasov
System.
B.A. Shadwick and P.J. Morrison, Institute for Fusion
Studies and Department of Physics, The University of Texas at
Austin, Austin TX, 78712.
1P 2 Singular Eigenfunctions for Shear Flow.
N.J. Balmforth and P.J.
Morrison, Institute for Fusion Studies and Department of Physics,
The University of Texas at Austin, Austin TX, 78712.
1P 3 Laser Induced Fluorescence Measurements of Waves in a Microwave
Plasma.
S. De Souza-Machado and F. Skiff, Institute for Plasma
Research University of Maryland, College Park MD 20742a
1P 4 Phase Space Reconstruction of Ion Response near an EICW Antenna.
D.P. Sheehan 1, M. Zintl, and J. Bowles 2, Department of Physics,
University of California, Irving. 1=University of San Diego, San
Diego, CA; 2=Naval Research Laboratory.
1P 5 Damping of Whistler Waves in a Large Laboratory Plasma.
C.L.
Rousculp, R.L. Stenzel, and J. M. Urrutia, UCLA Department of
Physics.
1P 6 Electron Current Pulses in Excess of the Saturation Limit:
Electromagnetic Fields and Radiation.
J.M. Urrutia, R.L. Stenzel,
and C.L. Rousculp, UCLA.
1P 7 Helicity in Whistler Wave Packets.
Reiner L. Stenzel, J.M. Urrutia,
and C.L. Rousculp, UCLA.
1P 8 Wave Collapse in Higher Dimensions.
V.F. Shvets, Auburn University,
AL 36849-5311, B.J. LeMesurer, Australian National University.
1P 9 Arrest of Wave Collapse in Magnetized Plasmas.
A. Melatos and P.A.
Robinson, University of Sydney, Australia.
1P 10 Nonlinear Langmuir-Wave Coalescence with Anisotropic Spectra.
A.J.
Willes, P.A. Robinson, and D.B. Melrose, University of Sydney,
Australia.
1P 11 Active Remote Sensing of the Upper Atmosphere with High Power Radio
Waves.
P.A. Bernhardt, Plasma Physics Division, Naval Research
Laboratory.
1P 12 Solitary Waves Near General Plasma Equilibria.
Mark Buchanan and J.
J. Dorning, University of Virginia.
1P 13 Solitary Wave-Beam Interaction in Collisionless Plasumas.
Paul C.
Kirklitelos, Mark Buchanan, and J.J. Dorning,University of Virginia.
1P 14 Universal trapping scaling on the unstable manifold for a
collisionless electrostatic mode.
J.D. Crawford, U. of Pittsburgh.
1P 15 Self-Generated Soliton in an Ion Beam-Plasma System.
S-G. Lee, D.
Diebold and N. Hershkowitz, University of Wisconsin-Madison.
1P 16 Production and Investigation of Ion Acoustic Shocks in a Single-
Chamber Multipolar Argon Plasma.
G. Bachet, F. Doveil and R.A.
Stern, Turbulence Plasma, I.M.T. 13451 Marseille, France.
1P 17 Experimental search for coherent structures in ITG turbulence.
P. Tham, A.K. Sen, Columbia University.
1P 18 Simulation on High Power Microwave Pulse Propagation.
J. Kim and
S.P. Kuo, Weber Research Institute, Polytechnic University,
Farmingdale, NY 11735.
1P 19 Spectral Breaking of High Power Microwave Pulse Caused by the
Self-generated Plasma.
A. Ren, S.P. Kuo, J. Kim, and E. Koretzky,
Weber Research Institute, Polytechnic University, Farmingdale,
NY 11735.
1P 20 Multidimensional Autoresonant Mode Conversion.
L. Friedland, Hebrew
U., Jerusalem, Israel.
1P 21 Bursting Processes in Plasmas and Relevant Nonlinear Model
Equations.
B. Basu, Phillips Laboratory, Hanscom AFB, MA and B.
Coppi, M.I.T., Cambridge, MA.
1P 22 MARFEs in Tokamak Edge Plasma: Pattern Formation under Nonlocal
Constraints.
B. Meerson 1, N. Petviashvili and T. Tajima, Institute
for Fusion Studies and Department of Physics, The University of
Texas at Austin. 1=Racah Institute of Physics, Hebrew University of
Jerusalem.
1Q 1 Nonlinear MHD Stability Studies of TFTR Plasmas.
M.H. Hughes and
M.W. Phillips, Northrop Grumman Corporation, Princeton, NJ.
1Q 2 Tearing Modes, Toroidal Flow and Shear Flow at the Edge.
F. Allais,
and T.E. Evans, University of Paris XI.
1Q 3 Onset of the Sawtooth Crash.
F.L. Waelbroeck and R. Fitzpatrick,
Institute for Fusion Studies, The University of Texas at Austin.
1Q 4 Anomalous Ion Heating Study in the TS-3 Magnetic Reconnection
Experiment.
Y. Ono, T. Akao, A. Morita, M. Katsurai, Univ. Tokyo;
M. Yamada, Princeton, Univ.
1Q 5 MRX Device for Study of 3-D Magnetic Reconnection.
F. Dahlgren, M.
Yamada, F.W. Perkins, N. Pomphrey, PPPL, Princeton U., Princeton,
NJ; Y. Ono and M. Katsurai, Univ. Tokyo.
1Q 6 The Nonlinear Stability of the 1/1 Mode in Tokamak Plasma Columns
With q(0)<1.
W. Stodiek, PPPL; M.H. Hughes and M.W. Phillips,
Northrop Grumman Corporation, Princeton, NJ.
1Q 7 Kinetic theory for magnetic island stability in tokmaks.
M. Zabiego,
X. Garbet, DRFC/SPPF, CE Cadarache, 13108 Saint-Paul-lez-durance,
France.
1Q 8 Viscosity Effects on the Nonlinear Dynamics of Magnetic Islands with
Resonant Magnetic Perturbations.
A.I. Smolyakov, E. Lazzaro 1, J.D.
Callen 2, A. Hirose, G.B. Re 1, Univ. of Saskatchewan, Canada.
1=Instituto di Fisica del Plasma, CNR-EUARATOM, Milano, Italy;
2=Univ. of Wisconsin-Madison, WI 53706, USA.
1Q 9 Helical temperature perturbations associated with tearing modes in
tokamak plasmas.
Richard Fitzpatrick, Institute for Fusion Studies,
UT Austin.
1Q 10 Nonlinear Dynamics of the m=1 Kink-Tearing Instability in a Modified
Magnetohydrodynamic Model.
A. Bhattacharjee and Xiaogang Wang, U. of
Iowa.
1Q 11 Simulation of Current Sheets in Two-Dimensional Coronal Loop with
X-type Neutral Lines.
Z.-W. Ma, A. Bhattacharjee, and Xiaogang Wang,
U. of Iowa.
1Q 12 A Global 3D Reconnection Model Involving Nulls and Its Implication
for Substorms.
Xiaogang Wang and A. Bhattacharjee, U. of Iowa.
1Q 13 Resistive and Collisionless Tearing Modes in the Earth's
Magnetotail.
B.G. Harrold and A. Bhattacharjee, U. of Iowa.
1Q 14 Neoclassical MHD Simulations of Bootstrap-Current-Driven Magnetic
Islands.
T.A. Gianakon, J.D. Callen, and C.C. Hegna, University of
Wisconsin-Madison.
1Q 15 Nonlinear Magnetic Island Dynamics in Tokamak Plasmas.
C.C. Hegna
and J.D. Callen, University of Wisconsin-Madison.
1Q 16 Collisonless Reconnection and Scattering of High Energy Particles.
B. Coppi and L. Sugiyama, M.I.T.
1Q 17 The Dynamics of MHD Waves at Magnetic Nulls.
A.B. Hassam and R.S.
Scheper, University of Maryland.
1Q 18 Dynamics of the Sawtooth Crash in the Early Nonlinear Stage.
B.
Rogers 1, T.M. Antonsen, Jr. 1, L. Zakharov 2. 1=University of
Maryland, College Park, MD; 2=Princeton Plasma Physics Lab,
Princeton, NJ.
1Q 19 Small Scale Magnetic Flux-Averaged Magnetohydrohynamics.
D. Pfirsch,
Max-Planck-Institut fur Plasmaphysik, Garching, Germany; and R.N.
Sudan, Cornell University, Ithaca, NY.
1Q 20 MHD generalization of the "tilting" instability: mechanism for
generation of the mean magnetic flux.
V.D. Shapiro and P.H. Diamond,
Physics Department, University of California, San Diago, La Jolla,
CA 92093-0319.
1Q 21 The principle of minimum rate of Ohmic dissipation applied to
driven, resistive, plasmas.
R. Farengo, Comision Nacional de Energia
Atomica Gerencis de Desarrollo; J.R. Sobehart, Center for Nonlinear
Studies, Los Alamos National LAboratory.
1Q 22 2D Analytical and Numerical Study of Drift Resistive Ballooning
Modes in Tokamak Plasmas.
S.V. Novakovski, P.N. Guzdar and C.S. Liu,
Institute for Plasma Research, University of Maryland, College Park,
MD 20742-3511.
1Q 23 Fractal Dimension of Edge Localized Modes.
D. Usikov, Y.-T. Lau and
P.N. Guzdar, Insitute for Plasma Research, University of Maryland,
College Park, MD 20742-3511.
1Q 24 Finite Ion Temperature Effects on the Nonlinear Evolution of the
Resistive Ballooning Modes in Tokamak Edge Plasmas.
J.F. Drake and
P.N. Guzdar, University of Maryland.
1R 1 Withdrawn
1R 2 An Unstructured Mesh Model of the SOL using Riemann-Delaunay
Triangulation.
A.P. Kuprat and A. H. Glasser, Los Alamos National
Laboratory.
1R 3 Nonlinear Dynamics of a Soliton by Split Step FFT Soliton
Propagator.
H. Singh, R. Uma and D. Subbarao, Centre for Energy
Studies and Department of Physics, Indian Institute of Technology,
Delhi, New Delhi 110016.
1R 4 Parallel computation of Monte-Carlo simulation code.
H. Xiao and P.
Geng, Institute for Fusion Studies, Department of Aerospace
Engineering, The University of Texas at Austin, Austin, Texas 78712.
1R 5 Statistical analysis of edge tokamak turbulence.
S. Benkadda, P.
Gabbai and A.D. Verga, Equipe Turbulence Plasma, Institut
Mediterraneen de Technologie, 13451 Marseille Cedex 20.
1R 6 An Implicit Algorithm for MHD Computations on Parallel Machines.
O.S. Jones and D.S. Eberhardt, University of Washington.
1R 7 Model of plasma sheath formation near surfaces in space.
Thomas L.
Morton, NYMA, Inc., Brook Park, OH.
1R 8 Parallel Electromagnetic PIC Simulation in Arbitrary 3-D Geometry.
David J. Larson, Scott Brandon, and Patrick Weidhaas, Lawrence
Livermore National Laboratory.
1R 9 Subgrid Models for 2D Tokamak Turbulence Simulations.
S.A. Smith,
G.W. Hammett and S.A. Orszag, Princeton University.
1R 10 A Symplectic PIC/Spectral Integrator for Plasma Simulations.
Isidoros Doxas, John R. Cary, University of Colorado, Boulder, CO
80309-0391.
1R 11 An Intuitive Basis for Modeling Radiative Divertors,
S I. Lippmann,
P.O. Box 910445, San Diego, CA 92191 (619)578-7370.
1R 12 Darwin Direct Implicit Particle-in-Cell (DADIPIC) Simulation of
Collisionless Heating in Inductive Plasma Processing Reactors.
M. R.
Gibbons and D. W. Hewett, LLNL.
1R 13 Magnetohydrodynamic Simulation of Fusion Problems on an
Unstructured, Adaptive Mesh.
D.D. Schnack, Z. Mikic, I. Lotatti,
D.L. Sachs, and P. Satyanarayana, SAIC, San Diego, CA; A. Turnbull,
General Atomics Corp., San Diego, CA; and A. Koniges, NERSC, LLNL,
Livermore, CA.
1R 14 A Distributed Computing Approach for Non-LTE Radiative Transport in
High Energy Density Plasmas.
J.A. Johansen, J.J. MacFarlane, and
G.A. Moses, University of Wisconsin-Madison.
1R 15 Progress on Gyrokinetic Simulations on Parallel Computers.
V.K.
Decyk, R. Sydora, UCLA; P.C. Liewer, J. Wang, JPL.
1R 16 Computer Simulation of Transport Driven Current in Tokamaks.
F.S.
Tsung, W.J. Nunan, J.M. Dawson, UCLA.
1R 17 Fluid Modelling of Divertors using the FMS code.
M. Day and B.
Merriman, University of California, San Diego.
1R 18 Numerical Methods for Computing Tokamak Equilibria with Poloidal and
Toroidal Flows.
B. Merriman and B.J. Lee, University of California,
San Diego.
1R 19 An Algorithm for "Rezoning" Particle-in-Cell Calculations.
G.
Lapenta and J. U. Brackbill, Los Alamos National Laboratory, Los
Alamos NM 87545.
1R 20 Computational Studies of Magnetized Target Fusion.
P. Sheehey, R.C.
Kirkpatrick, and I. R. Lindemuth, Los Alamos National Laboratory,
Los Alamos, NM 87545.
1R 21 Numerical Analysis of Diverted Tokamak Edge Plasmas.
K.H. Im, D.Q.
Kim, and S.H. Hong, Department of Nuclear Engineering, Seoul
National University.
1R 22 DCON-$\psi$ Stability Code for Ideal and Nonideal Tokamak Plasma.
L. E. Zakharov, V. Drozdov 1, Princeton University. 1=Keldysh
Institute of Applied Mathematics.
1R 23 Improvements to the PIES Code and Applications.
D.A. Monticello, J.
L. Johnson, and A. H. Reiman, Princeton University.
1R 24 Gyrokinetic simulations of ITG mode turbulence and transport using
TPC.
M. J. LeBrun, T. Tajima, Institute for Fusion Studies.
1S 1 First Results of the LHCD Experiments on TdeV.
Y. Demers 1, A.
Cote 2, C. Cote 3, R. Decoste 2, P. Jacquet 3, P. Bonoli 4, V. Fuchs
2, I.P. Sharofsky 1, and the TdeV Team, Centre canadien de fusion
magnetique, Varennes, Quebec, J3X 1S1. 1=MPB Technologies, Pointe-
Claire (Quebec) Canada; 2=Hydro-Quebec (Quebec) Canada;
3=INRS-Energie, Varennes (Quebec) Canada; 4=MIT, Plasma Fusion
Center.
1S 2 Energy Confinement Studies on TdeV.
A. Cote 1, M. St-Onge 3, G. Abel
2, C. Cote 2, R. Decoste 1, Y. Demers 3, E. Haddad 3, J.-L.
Lachambre 1, G. Le Clair 3, H.H. Mai 2, F. Martin 2, D. Michaud 3,
N. Richard 3 and M.M. Shoucri 1, Centre canadien de fusion
magnetique, Varennes, Qc, Canada. 1=Hydro-Quebec; 2=INRS-Energie et
Materiaux; 3=MPB Technologies.
1S 3 Characterization of the suprathermal electrons produced during LHCD
experiments on TdeV.
C. Cote 1, Y. Demers 2, P. Brooker 2, S. Gulick
3, J.-L. Lachambre 4, Centre canadien de fusion magnetique,Varennes,
Quebec, Canada J3X 1S1. 1=INRS-Energie, Varennes (Quebec) Canada;
2=MPB Technologies Inc., Dorval (Quebec) Canada; 3=University of
Maryland, College Park MD.; 4=Hydro-Quebec, Varennes(Quebec) Canada.
1S 4 Impurity Transport and Levels in TdeV Central Plasma During HF
Heating and Divertor Plate Biasing.
E. Haddad 1, H.H. Mai 2, B.C.
Gregory 2, A. Ratel 2, G. Ratel 3, L. Hrynkiw 3, Centre Canadien de
Fusion Magnetique, (Quebec) Canada. 1=MPB Technologies Inc., Dorval
(Quebec) Canada; 2=INRS-Energie, Varennes (Quebec) Canada;
3=Hydro-Quebec, Varennes (Quebec) Canada.
1S 5 Effect of RF and Biasing Operating Modes on Radiative losses on the
TdeV Tokamak.
N. Richard 1, J. Mailloux 2, R. Marchand 2, A.
Sarkissian 2, B. Stansfield 2, W. Zang 2, Centre canadien de fusion
magnetique, Varennes, Quebec, Canada, J3X 1S1. 1=MPB Technologies,
Pointe-Claire (Quebec) Canada; 2=INRS-Energie, Varennes (Quebec)
Canada.
1S 6 Compact 10-150 keV, 4 channel, X-ray spectrometer for the TdeV
tokamak.
P. Brooker 1, Y. Leblanc 2, G. Ratel 3, C. Janicki
Y. Demers 1, Centre canadien de fusion magnetique, Varennes, Canada.
1=MPB Technologies, Dorval, Quebec, Canada; 2=Inspectech 2000,
Varennes, Quebec, Canada; 3=Hydro-Quebec, Varennes, Quebec, Canada.
1S 7 Measurement of suprathermal electron distribution function by
extraordinary wave absorption in TdeV.
S. Gulick 1, D. Boyd 1, F.
Skiff 1, R. Neufeld 2, D. Pinsonneault 1. 1=Institute for Plasma
Research, University of Maryland.
1S 8 Spatial Resolution of LHCD Electron Distribution Functions in the
Tokamak de Varennes.
D. Boyd, F. Skiff and S. Gulick, Institute for
Plasma Research, Univ. of Maryland, College Park, MD 20742.
1S 9 Sensitivity and Resolution of Electron Cyclotron Transmission
Diagnostics.
F. Skiff, D. . Boyd and S. Gulick, Institute for Plasma
Research, University of Maryland, College Park, MD.
1S 10 Power balance with LH heating an J.
Mailloux 1, C. Cote 1, Y. Demers
2, N. Richard 2, B. Terreault 1 and W. Zhang 1, Centre canadien de
fusion magnetique, Varennes, J3X 1S1. 1=INRS-Energie et Materiaux,
Varennes, Quebec, Canada; 2=MPB Technologies INC, Dorval, Quebec,
Canada.
1S 11 Flush probe measurements of the plasma parameters in front of the
divertor plates of TdeV.
J.P. Gunn 1, C. Boucher 1, B.L. Stansfield
1, Centre Canadien de Fusion Magnetique, Varennes, Quebec, J3X 1S1.
1=INRS-Energie et Materiaux, Varennes, Quebec, J3X 1S1.
1S 12 Radiation from Edge Plasma: Comparison between Modelling and
Experiment.
R. Marchand 1, J.L. Gauvreau 2, G. Abel 1, B. Stansfield
1, N. Richard 3, A. Sarkissian 1, Centre Canadien de Fusion
Magnetique, Varennes (Quebec) Canada. 1=INRS-Energie et Materiaux,
Varennes, Canada; 2=Hydro-Quebec, Varennes, Canada; 3=MPB
Technologies, Dorval, Canada.
1S 13 Plasma flow in the SOL of TdeV.
C. Boucher 1, G. Abel 1, J.-L.
Gauvreau 2, J.P. Gunn 1, C.S. Maclatchy 3, and B.L. Stansfield 1,
Centre Canadien de Fusion Magnetique, Varennes, Quebec, Canada
J3X 1S1. 1=INRS-Energie et Materiaux, Varennes, Quebec, Canada;
2=Hydro-Quebec, Varennes, Quebec, Canada; 3=Acadia University,
Wolfville, Nova Scotia, Canada.
1S 14 Spatially Resolved Spectroscopic Profiles in TdeV.
J.-L. Gauvreau 1,
G. Abel 2, and I. Girard 1, Centre canadien de fusion magnetique,
Varennes, Qc, Canada. 1=Hydro-Quebec, Varennes, Quebec, Canada;
2=INRS-Energie et Materiaux, Varennes, Quebec, Canada.
1S 15 Potential and Density Fluctuations in the Edge of the TdeV Tokamak
using the Thallium Neutral Beam Probe.
J.A. Beckstead, S.C. Aceto,
J. Castracane, E. Saravia and J.T. Woo, InterScience. Inc.
1S 16 Electrode biasing experiment on TdeV.
D. Michaud, J.L. Lachambre, G.
Abel, C. Boucher, A. Cote, J.L. Gauvreau, CCFM, Canada.
1S 17 AM Modulation Reflectometry for Edge Density Measurements in TdeV.
D. Pinsonneault 1, B. Quirion 2, C. Legros 3, Centre canadien de
fusion magnetique, Varennes, Canada, J3X 1S1. 1-INRS-Energie et
materiaux, Varennes (Quebec) Canada; 2=Decatron, St-Bruno (Quebec)
Canada; 3=Inspectech 2000, St-Sulpice (Quebec) Canada.
1S 18 Plasma Discharge Control System in PBX-M.
M. Okabayashi, R. Bell, G.
Gettelfinger, R. Hatcher, R. Kaita, L. Lagin, F. Levinton 1, and P.
Sichta, Princeton U. 1=Fusion Physics and Technology, Inc.
1S 19 "Integrated Shell" Approach for Vertical Position Control.
R.
Hatcher and M. Okabayashi, Princeton Univ.
1S 20 Equilibrium Modification with Lower Hybrid Current Drive in PBX-M.
R. Kaita, S. Batha 1, R. Bell, S. Bernabei, M. Chance, T.K. Chu,
J. Dunlap 2, A. England 2, G. Gettelfinger, N. Greenough, R.
Hatcher, S. Hirshman 2, D. Ignat, R. Isler 2, S. Jardin, S. Jones 3,
S. Kaye, J. Kesner 3, H. Kugel, B. LeBlanc, F. Levinton 1, S.
Luckhardt 3, J. Manickam, M. Okabayashi, M. Ono, F. Paoletti 3, S.
Paul, A. Post-Zwicker 2, S. Preische, N. Sauthoff, L. Schmitz 4, S.
Sesnic, Y. Sun, H. Takahashi, M. Talvard 5, W. Tighe, G. Tynan 4, E.
Valeo, S. von Goeler, K. Voss, and A. Zolfaghari 3, Princeton U.
1=Fusion Physics and Technology, Inc., Torrance, CA; 2=Oak Ridge
National Laboratory, Oak Ridge, TN; 3=Massachusetts Institute of
Technology, Cambridge, MA; 4=University of California at Los
Angeles, Los Angeles, CA; 5=TORE-SUPRA, Cadarache, France.
1S 21 MHD Activity during Lower Hybrid Current Profile Modification in
PBX-M.
M. Talvard 1, R. Bell, S. Bernabei, D. Ignat, R. Kaita, S.
Kaye, M. Okabayashi, S. Sesnic and S. von Goeler, Princeton Plasma
Physics Laboratory. 1=TORE-SUPRA, Cadarache, France.
1S 22 Hard X-ray Hot Spots during Lower Hybrid Current Drive on PBX-M.
J. Yun, S. von Goeler, R. Kaita, S. Bernabei, S. Jones, H. Kugel, P.
Roney, and L. Schmitz 1, Princeton University, Plasma Physics
Laboratory. 1=Institute for Plasma and Fusion Research, UCLA, Los
Angeles, CA 90024.
1S 23 Radial Distribution of Superthermal Electrons Measured with ECE.
S. Preische, P.C. Efthimion, S.M. Kaye, Princeton University.
1S 24 CH-Mode Studies Overview and Update.
J. Dunlap 1, R.Kaita, B.
LeBlanc, F. Levinton, M. Okabayashi, M. Ono, S. Sesnic, W. Tighe,
and the PBX-M Group, Princeton Plasma Physics Laboratory. 1=ORNL.
1S 25 Modification of MHD During IBW and Neutral Beam Injection in PBX-M.
S. Sesnic, R. Kaita, S. Kaye, B. Leblanc, M. Okabayashi, M. Ono, and
the PBX-M Group, Princeton Plasma Physics Laboratory.
1S 26 Experimental Plans for the CH-Mode and the "$\alpha$"-Channeling
Simulation with IBW in PBX-M.
M. Ono, N. Fisch, D. Ignat, R. Kaita,
H. Kugel, B. LeBlanc, F. Levinton, M. Okabayashi, S. Sesnic, W.
Tighe, E. Valeo and the PBX-M group, Princeton University.
1S 27 Prompt Sawtooth Stabilization in Lower Hybrid RF Experiments on
PBX-M: Part II.
S. Migliuolo, S. Luckhardt, J. Kesner, F. Paoletti,
A. Zolfaghari, MIT; S. Bernabei, M. Okabayashi, and the PBX-M Group,
PPPL.
1S 28 Prompt Stabilization of Sawteeth in Lower-Hybrid RF Experiments on
PBX-M: Part I.
S.C. Luckhardt, S. Migliuolo, J. Kesner, S. Jones, F.
Paoletti, A. Zolfaghari, MIT Plasma Fusion Center; and S. Bernabei,
M. Okabayashi, S. Sesnic, and the PBX-M group, Princeton University.
1S 29 Measurement of Internal MHD Fluctuations in PBX-M by an ECE
Heterodyne Radiometer.
A.M. Zolfaghari, S. Luckhardt, P. P. Woskov,
MIT; R. Kaita, Princeton University.
1T 1 Correlation of flow and phase velocity during sawteeth and locked
modes in MST.
A.F. Almagri, D.J. Den Hartog, B.E. Chapman, J.T.
Chapman, S.C. Prager, J.S. Sarff, University of Wisconsin-Madison.
1T 2 Measurement of Flow Velocity Fluctuations and the MHD Dynamo in the
MST Reversed Field Pinch.
J.T. Chapman, D.J. Den Hartog, A.F.
Almagri, R.J. Fonck, S.C. Prager, and J.S. Sarff, University of
Wisconsin-Madison.
1T 3 Electrostatic Current Source for Current Profile Modification and
Fluctuation Reduction in MST.
J.S. Sarff, A.F. Almagri, C.-S.
Chiang, D.J. Craig, G. Fiksel, S.C. Prager, University of
Wisconsin-Madison.
1T 4 Correlation of Magnetic Fluctuations and Thermal Energy Density
during a Sawtooth Oscillation in MST.
M. Cekic, D.J. Den Hartog, J.
S. Sarff, and S.C. Prager, University of Wisconsin-Madison.
1T 5 Conservation of Magnetic Helicity during Plasma Relaxation in the
MST RFP.
H. Ji, S.C. Prager, and J.S. Sarff, Department of Physics,
University of Wisconsin.
1T 6 Accessibility of Lower-Hybrid Current Drive in the RFX
Reversed- Field Pinch.
R. Dziubek, S. Hokin, Department of Physics,
University of Wisconsin-Madison; R. Harvey, General Atomics,
San Diego; E. Uchimoto, Department of Physics and Astronomy,
University of
Montana, Missoula.
1T 7 Fluctuation Reduction in a Reversed Field Pinch Using Lower Hybrid
Poloidal Current Drive.
E. Uchimoto 1, M. Cekic, R.W. Harvey 2, C.
Litwin, S.C. Prager, J.S. Sarff, and C.R. Sovinec, University of
Wisconsin-Madison. 1=Dept. of Physics & Astronomy, Univ. of Montana,
Missoula, MT 59812; 2=General Atomics, San Diego, CA 92186.
1T 8 Conceptual Design of a Lower-Hybrid Wave Antenna for a Reversed
Field Pinch.
M.A. Thomas, M. Cekic, E. Uchimoto 1, T. C. Litwin, T.
W. Lovell, S.C. Prager, and J.S. Sarff, University of Wisconsin-
Madison. 1=Dept. of Physics & Astronomy, Univ. of Montana, Missoula,
MT 59812.
1T 9 Proton and Impurity Ion Temperature Profiles in MST.
S. Hokin, Dept.
of Physics, University of Wisconsin-Madison; E. Scime, Los Alamos
National Laboratory; C. Watts, Auburn University/TEXT.
1T 10 Qulescent discharges in the MST reversed-field pinch.
B.E. Chapman,
A.F. Almagri, D.J. Den Hartog, S.C. Prager, J.S. Sarff, and C.S.
Sovinec, University of Wisconsin-Madison.
1T 11 Evidence for an Inertial Range in the Microturbulent Spectrum of the
RFP Plasma.
M.R. Stoneking, S. Hokin, P. Terry, H. Ji, University of
Wisconsin-Madison.
1T 12 Edge Dynamo Mechanisms in the RFPs.
S.C. Prager, H. Ji, A.F.
Almagri, and J.S. Sarff, University of Wisconsin; H. Toyama,
University of Tokyo; K. Miyamoto, Seikei University; K. Hattori, Y.
Maejima, and Y. Hirano, Electrotechnical Laboratory.
1T 13 Edge Ion Measurements in MST.
N. Crocker, G. Fiksel, and S.C.
Prager, Dept. of Physics, University of Wisconsin, Madison, WI.
1T 14 Shells, Gaps, Fluctuations and Loop-Voltages in the Reversed Field
Pinch Experiment, ZT-40M.
J.A. Phillips, D.A. Baker and R.F.
Gribble, Los Alamos National Laboratory, Los Alamos, NM 87544.
1T 15 Effect of Aspect ratio on RFP Dynamics.
P. Nordlund, S. Mazur, J.
Scheffel, H. Satherblom, J.R. Drake, Royal Institute of Technology-
Stockholm, Sweden; Y.L. Ho, D.D. Schnack, SAIC-San Diego, CA.
1T 16 Soft X-ray Measurements in the Reversatron RFP.
David Alexander and
Scott Robertson, University of Colorado, Boulder, CO 80309.
1T 17 Possibility of a Reversed-Field Pinch with a Toroidally Symmetric
Resistive Shell.
D.A. Baker, J.M. Finn, J.A. Phillips, and R.F.
Gribble, Los Alamos National Laboratory, Los Alamos, NM 87545.
1T 18 Poloidal Divertor Expertments in the STE-2 RFP.
M. Iida, D.
Ishijima, T. Miyagi, S. Masamune, H. Oshiyama, Department of
Electronics and Information Science, Kyoto Institute of Technology,
Matsugasaki, Sakyo-ku, Kyoto 606, Japan.
1T 19 Initial Current Drive and Stability Studies on the Helicity Injected
Tokamak.
D.J. Orvis, T.R. Jarboe, B.A. Nelson, and J.A. Rogers, AERB
FL-10, University of Washington.
1T 20 Confinement Studies on HIT.
L. Zhou, T.R. Jarbor, B.A. Nelson, and
J. Xie, AERB FL-10, University of Washington.
1T 21 Density Study of the HIT Plasma.
J. Xie, T.R. Jarboe, and B.A.
Nelson, AERB, FL-10, University of Washington.
1T 22 Helicity Source Studies on the HIT Experiment.
A. Martin, T.R.
Jarboe, O. Jones, and B.A. Nelson, AERB, FL-10, University of
Washington.
1T 23 3D MHD simulations of DC Helicity Injection in Tokamak
Configurations.
C.R. Sovinec and S.C. Prager, University of
Wisconsin-Madison.
1T 24 A Spheromak Experiment to Examine Core Energy Confinement During
Sustainment.
E.B. Hooper, J.H. Hammer, L.D. Pearlstein, L.J.
Perkins, Lawrence Livermore National Laboratory; T.K. Fowler,
University of California; and C.W. Barnes, J.C. Fernandez, Los
Alamos National Laboratory.
1T 25 Specification of Optimal Equilibrium Parameters in the FACT and
SPHEX Spheromaks.
R. Kenny, M. Nagata, T. Uyama and the SPHEX*
Group, Himeji Institute of Technology, *=UMIST, Manchester.
1T 26 MHD Simulation of Relaxation Process in Flux-Core Spheromaks.
N.
Amemiya, T. Hanafusa, Yokohama National University.
1T 27 Formation of Field-Reversed Ion Rings in a Background Plasma.
B.V.
Oliver, Yu. A. Omelchenko, D.D. Ryutov and R.N. Sudan, Cornell
University, Ithaca, NY.
1T 28 Density Control of a Field-Reversed-Configuration Plasma.
Y.Nogi, S.
Shimamura, T. Takahashi, College of Science and Technology, Nihon
Univ.
1T 29 Low Frequency Stability of Long Annular Layer of Large Orbit
Energetic Ions In a Field Reversed Configuration.
Michl Binderbauer
and Norman Rostoker, Department of Physics, University of
California, Irvine.
1T 30 Confinement in field-reversed configurations with low-frequency
drift (LFD) transport.
L.C. Steinhauer, University of Washington;
N.A. Krall, Krall Associates; and A. Ishida, Niigata University.
1T 31 Ideal local modes of field reversed configurations.
A. Ishida, N.
Shibata, Niigata University, and L.C. Steinhauer, University of
Washington.
1T 32 Results from MARAUDER compact toroid experiments in self-similar
electrodes.
C.D. Holmberg and the MAURAUDER experimental staff,
Phillips Laboratory.
1T 33 Pressure balance and rf-plasma coupling during FRC formation.
H.R.
Zwi, A.Y. Wong, A. Kuthi, and T. Fukuchi, UCLA.
1T 34 SUPRSLUG: An enhanced slug code for modelling compact toroid
dynamics.
G.F. Kiuttu, Phillips Laboratory.
1T 35 Confinement Physics of the Gasdynamic Mirror.
T. Kammash, D.L.
Galbraith and M.J. Lee, The University of Michigan.
1T 36 First experiments in the end sell of axisymmetric tandem mirror
AMBAL-M.
V.I. Davydenko, T.D. Akhmetov, V.S. Belkin, E.D. Bender, E.
A. Gilev, G.I. Dimov, A.N. Dranichnikov, A.A. Kabantsev, V.M.
Karliner, Yu.V. Kovalenko, A.S. Kupriyanov, V.Ya. Savkin, V.G.
Sokolov, S. Yu. Taskaev, V.N. Filippov, Budker Institute of Nuclear
Physics 630090, Novosibirsk, Russia.
1T 37 Magnetoelectric Confinement - A Computer Study of Its Stability.
Thomas H. Stix and Hideo Okuda, Princeton University.
1T 38 First Experiments in the AMBAL-M Mirror System with the Hot Target
Plasma.
A.A. Kabantsev, G.I. Dimov, V.I. Davydenko, V.G. Sokolov,
S.Yu. Taskaev, Budker Institute of Nuclear Physics 630090,
Novosibirsk, Russia.
2IA 1 Isotopic Scaling of Confinement in Deuterium-Tritium Plasmas.
S.D. Scott, Princeton Plasma Physics Laboratory.
2IA 2 Deuterium-Tritium H-mode Studies on TFTR.
C.E. Bush, Oak Ridge National Laboratory.
2IA 3 Results of Confined Alpha Particle Measurements in TFTR.
R.K. Fisher, General Atomics.
2IB 1 Stability and Confinement Measurements in a Large Field Reversed
Configuration Experiment.
J. Slough, University of Washington.
2IB 2 Long Pulse Experiments on the ATF Stellarator.
T.C. Jernigan,
Oak Ridge National Laboratory.
2IB 3 Tandem Mirror Experiments in Gamma 10.
T. Tamano, University of
Tsukuba, Japan.
2E 1 Smoothing of Speckle Irradiation Patterns by Temporal Evolution of
the Target Corona.
R.W. Short, LLE, U. of Rochester.
2E 2 Spreading of Intense Laser Beams Due to Ponderomotive Filamentation.
S.C. Wilks, P.E. Young, J. Hammer, M. Tabak, and W.L. Kruer,
Lawrence Livermore National Laboratory.
2E 3 Leaky Filaments and Light Beam Break-Up into Equilibrium Filaments.
T.W. Johnston, F. Vidal and D. Frechette, INRS-Energie et Materiaux
C.P. 1020 Varennes, Quebec, J3X 1S2 Canada.
2E 4 Parametric Instability of Bernstein and Fluid Modes in Laser-
Produced Plasma.
A. Simon and R.W. Short, LLE, U. of Rochester.
2E 5 Evolution of Stimulated Raman into Compton Scattering through Wave-
Breaking in a Tunnel-Ionized Plasma.
C.E. Clayton, M.J. Everett, A.
Lal, D. Gordon, W. Mori, C. Joshi, Department of Electrical
Engineering, UCLA.
2E 6 Coupling Between Electron Plasma Waves.
M.J. Everett, C.E. Clayton,
A. Lal, W. Mori, and C. Joshi, Electrical Engineering Department,
UCLA.
2E 7 Nonlocal Electron Transport in the Presence of High-Intensity Laser
Irradiation.
E.M. Epperlein and R.W. Short, LLE, U. of Rochester.
2E 8 Nonstationary and nonlocal electron heat transport in laser-produced
plasmas.
V.T. Tikhonchuk 1, V. Yu Bychenkov 1, J. Myatt, and W.
Rozmus, Department of Physics, Univeristy of Alberta, Edmonton,
Canada. 1=P.N. Lebdev Physics Institute, Russian Academy of
Sciences, Moscow, Russia.
2E 9 Electron Acceleration by Evanescent Waves in Overdense Plasmas.
T.-Y. Brian Yang, William L. Kruer, and Scott C. Wilks, Lawrence
Livermore National Laboratory.
2E 10 Competition between Target Self-Emission and Soft X-Ray
Backlighting.
R.S. Craxton, LLE, U. of Rochester; M. Dunne, and O.
Willi, Imperial College.
2E 11 Multi-Colored-Interferogram Recorded in R-G-B Color Film to the
Density Distribution of Laser-Produced Plasmas.
H. Yoshida, Y.
Sakagami, M. Kato, T. Mizutani, Y. Suzuki, Y. Sano, H. Oshita, Gifu
University, Japan.
2F 1 Ballooning Stability of High Confinement Discharges in DIII-D
Including Measured Rotation Profile.
R.L. Miller, L.L. Lao, T.S.
Taylor, General Atomics.
2F 2 Comparative Analysis of the Thermalizing Instabilities of Plasmas
with Non Bimaxwellian Distribution Functions.
N.T. Gladd and S.H.
Brecht, Berkeley Research Associates.
2F 3 The Importance of Electron Energy Transport Due to Electron Plasma
Waves.
Alan A. Ware, Institute for Fusion Studies, The University of
Texas at Austin.
2F 4 Magnetic Moment of Bounce Motion and its Consequences.
Tian-Sen
Huang, Department of Physics, Prairie View A&M University.
2F 5 Fluid Description of Kinetic Modes.
Glenn Beach and Y.Y. Lau,
Department of Nuclear Engineering, U. Michigan, Ann Arbor, MI
48109-2104.
2F 6 Anomalous Transport for Large Ion Gyro-radii.
D.F. Duchs, MPI fur
Plasmaphysik, D-85740 Garching, Germany.
2F 7 Potential Surface Type Waves in 'Metal-Magnetoactive Plasma'
Structure.
N. Azarenkov, M. Dolgopolov, Kaharkiv State University,
310077, Ukraine.
2F 8 The effect of Alfvenon Dynamics on Driven Reconnection.
Yan Song and
Robert L. Lysak, School of Physics and Astronomy, University of
Minnesota.
2F 9 Two-Step Evolution of Collisionless Driven Reconnection.
R.
Horiuchi, T. Sato, National Institute for Fusion Science, Japan.
2F 10 Transition to Turbulence in a Crossed-Field Gap.
Peggy Christenson
and Y.Y. Lau, Intense Energy Beam Interaction Laboratory, Nuclear
Engineering Dept., U. Michigan, Ann Arbor, MI 48109-2104.
2F 11 Electrostatic eigenmodes of a cylindrical nonneutral plasma.
D.L.
Book, Enigmatics, Inc., P.O. Box 11834, Washington, DC 20008.
2F 12 The Unstable l=1 Diocotron Mode for Hollow Electron Columns in a
Gyrokinetic Model.
S. Neil Rasband, Department of Physics and
Astronomy, Brigham Young University, Provo, Utah 84602.
2P 1 Inhomogeneous Emitter from the Five Branch Cyclotron Layer.
C.S. Ng,
V.F. Shvets, and D.G. Swanson, Auburn Univeristy, AL 36849-5311.USA.
2P 2 The Effects of Reflection on ECE Emission at Electron Cyclotron
Harmonics.
D.G. Swanson and Y.C. Ng, Auburn Univeristy, AL 36849.
2P 3 Wave Propagation near Cyclotron Resonance in the Presence of Large
Larmor Radius Particles.
R.A. Cairns 1, C.N. Lashmore-Davies 2, H.
Holt 1, and D.C. McDonald 1. 1=University of St. Andrews, St.
Andrews, UK; 2=UKAEA Government Division, Fusion , Culham, UK.
2P 4 Electromagnetic Wave Scattering in an Inhomogeneous Plasma
Characterized by Periodic Structure.
Ruthie Lyle, J. Huang, and S.P.
Kuo, Weber Research Institute, Polytechnic University, New York.
2P 5 Electron Cyclotron Waves in a Highly Inhomogeneous plasma.
Brian E.
Chapman, J.E. Scharer, W. Shen, M.H. Bettenhausen, University of
Wisconsin-Madison.
2P 6 Modelling of Helicon Sources for a Variety of Inductive Coil Antenna
Couplers.
Y. Mouzouris, J.E. Scharer, M.H. Bettenhausen, and W Shen,
University of Wisconsin-Madison.
2P 7 Experimental Study of XUV Laser Produced Plasma Sheet for a
Microwave Agile Mirror Application.
W. Shen, J.E. Scharer, B.G.
Porter, N.T. Lam and Y. Mouzouris, Electrical and Computer
Engineering Department, University of Wisconsin-Madison.
2P 8 Microwave Reflection from an XUV Laser Generated Planar Plasma
Sheet.
B.G. Porter, J.E. Scharer, W. Shen and N.T. Lam, University
of Wisconsin-Madison.
2P 9 Eikonalysis of the Vlasov Equation in the Gyrofrequency Range for
Tokamak Geometry.
E.R. Tracy, Physics Dept., College of William and
Mary; and A.N. Kaufman, LBL and Physics Dept., Univ. of Calif.
Berkeley.
2P 10 Super-Emission of Negative-Energy Bernstein Waves by Alpha-
Particles.
A.N. Kaufman and A.J. Brizard, Lawrence Berkeley
Laboratory.
2P 11 Laboratory Study of Lower Hybrid Wave Interactions with a Density
Striation.
Steven Rosenberg, Walter Gekelman, James Maggs,
Department of Physics, UCLA, 90024.
2P 12 The Anatomy of Whistler Wave Mode Conversion at a Density Striation.
Jim Bamber, Walter Gekelman, James Maggs, Department of Physics,
UCLA, 90024.
2P 13 Behavior of Shear Alfven Waves in the Presence of Temporal and
Spatial Nonuniformities.
D. Leneman, W. Gekelman, J. Maggs, S.
Vincena, UCLA.
2P 14 Experimental Observations of the Interaction of Alfven Wave Cones.
W. Gekelman, S. Vincena, D. Leneman, UCLA Physics.
2P 15 Eigenmodes and Stability of Narrow Density Striations.
G.J. Morales,
J.E. Maggs, R.S. Loritsch, and J. Penano, UCLA.
2P 16 Magnetic Fluctuations of a Controlled Density Striation.
J.E. Maggs,
G.J. Morales, D. Leneman, and W. Gekelman, UCLA.
2P 17 Ion Wave Propagation into the Plasma Sheath.
K.L. Cartwright and
C.K. Birdsall, EECS Department, UC Berkeley, Berkeley, CA 94720.
2P 18 Particle simulation of surface waves.
D.J. Cooperberg and C.K.
Birdsall, University of California at Berkeley.
2P 19 On the Alfven Resonance in a Sheet Pinch with $k \parallel B_0$.
J.A. Tataronis and S. Rauf, University of Wisconsin-Madison.
2P 20 Spatial Structure of Magnetosonic Whistler Eigenmodes in Cylindrical
Geometry.
C. Riconda, B. Coppi, N. Asherie, M.I.T.
2P 21 Emission avobe the Ion Cyclotron Frequency Induced by Fusion
Reaction Products.
N. Asherie, B. Coppi and C. Riconda, M.I.T.
2P 22 Surface Waves Propagation Along Small Azimuth in Tokamaks.
Girka I.
A., Girka V.A., Kharkiv State University, 310077, Ukraine.
2Q 1 Electron Acceleration by Transverse Electromagnetic Wave.
N. Yugami,
K. Kikuta, S. Sanjou, Y. Nishida, Utsunomiya University, Japan.
2Q 2 A Practical Free Wave Accelerator.
John G. Woodworth, Lawrence
Livermore National Laboratory, and Authur K. Kerman, Massachusetts
Institute of Technology.
2Q 3 Nonlinear Laser Electron Acceleration in Vacuum.
F.V. Hartemann,
S.N. Fochs, G.P. Le Sage and N.C. Luhmann, Jr., DAS, UC Davis; M.D.
Perry and G.A. Westenskow, LLNL.
2Q 4 Development of 10 $\mu$m Picosecond, 1-10 Hz Repetition Rate, Laser
System for Electron Acceleration.
V.V. Appolinov 1, A.M. Prokhorov
1, and V. Stefan, Tesla Laboratories, Inc., La Jolla, Ca; and V.R.
Sorochenko, General Physics Institute, Russian Academy of Sciences,
Moscow, Russia. 1=General Physics Institute, Russian Academy of
Sciences, Moscow, Russia.
2Q 5 Cyclotron Autoresonance Accelerator (CARA) with Tapered Wall Radius
and Tapered Guide Field.
Changbiao Wang, Yale Univ; and J.L.
Hirshfield, Omega-P, Inc. and Yale Univ.
2Q 6 Microwave Inverse Free-Electron-Laser Accelerator (MIFELA).
T.C.
Marshall, T.B. Zhang, Columbia Univ.; P. Sprangle, NRL; A.K.
Ganguly, Omega-P, Inc.; and J.L. Hirshfield, Omega-P, Inc. and Yale
Univ.
2Q 7 Electron acceleration by Langmuir waves in an inhomogeneous plasma.
M. Baine, S.K. Ride, V.I. Shevchenko, R. Bingham, CalSpace
Institute, University of California, San Diego, La Jolla, CA 92093-
0407.
2Q 8 Electron Beam Energy Spectrum, Angular Distribution, Trapping, and
Stageing in Plasma Wave Accelerators.
R.L. Williams and M. Mochena,
Florida A&M University.
2Q 9 Simulatin of the Electron-Hose Instability in the Plasma Wake-Field
Accelerator.
J. Krall and G. J oyce, Naval Research Laboratory.
2Q 10 Ion Wakefield Excitation in Double Plasma Device.
H. Tamura, N.
Yugami and Y. Nishida, Utsunomiya University, Japan.
2Q 11 Large Ion Plasma Wakefield Excitation in short Microwave Plasma
Interaction.
Y. Nishida, N. Yugami, Utsunomiya University, Japan;
B. Cros and G. Mattheiussent, Paris University, France.
2Q 12 Suppressing Beam Break Up in a Relativistic Klystron Two-Beam
Accelerator.
T. Houck, Lawrence Livermore National Laboratory, and
N. Goffeney, Lawrence Berkeley Laboratory.
2Q 13 Study of Longitudinal Dynamics of a Relativistic Klystron Two-Beam
Accelerator.
H. Li and S. Yu.
2Q 14 Design Studies of a Novel Two-Beam Accelerator (Twobetron).
R.M.
Gilgenbach, Y.Y. Lau, Ya S. Derbenev, J. Luginsland, J.M. Hochman,
M.T. Walter, and C.H. Ching, Intense Energy Beam Interaction
Laboratory, Nuclear Eng. Dept., Univ. of Michigan, Ann Arbor, MI
48109-2104.
2Q 15 Beat Wave Cooling.
Y. Kishimoto 1, T. Tajima, D.L.. Fisher, and K.
Mima 2, Institute for Fusion Studies, The University of Texas at
Austin. 1=Naka Fusion Research Establishment, JAERI, Japan;
2=Institute of Laser Engineering, Osaka Univeristy, Japan.
2Q 16 $N^2$ Radiation Cooling of Charged Particle Beams.
J.K. Koga, T.
Tajima 1, and Y. Kishimoto, Advanced Science Research Center, JAERI.
1=Department of Physics, The University of Texas at Austin.
2Q 17 Free Electron Laser Operation near the Cutoff Frequency of a
Waveguide Mode.
Y. Aktas, University of North Carolina at Charlotte;
J.E. Willett, University of Missouri-Columbia; H. Mehdian, Teacher
Training University, Tehran, Iran; and B. Maraghechi, Center for
Theoretical Physics and Mathematics, A.E.O.I. and Amir Kabir
University, Tehran, Iran.
2Q 18 Computationally Efficient Spectral Analysis Of An FEL Oscillator
Using Green's Function Analysis.
S. Ishii 1, G. Shvets, and J.S.
Wurtele, Massachusetts Institute of Technology. 1=Mitshubishi Heavy
Industries, Ltd.
2Q 19 Efficient Recirculating Free-Electron Lasers.
John R. Cary, Scott
Robertson, Scott Hendrickson, University of Colorado, Boulder, CO
80309-0391.
2Q 20 NRL Ubitron Amplifier Performance.
D.E. Pershing 1, R.D. Sheeley 1,
R.H. Jackson, and H.P. Freund 2, Naval Research Laboratory.
1=Mission Research Corporation, Newington, VA 22122; 2=Science
Applications International Corporation, McLean, VA 22102.
2Q 21 Design and Performance Calculations for a $K_a$-Band CHI Wiggler
Ubitron Amplifier.
J.M. Taccetti 1, R.H. Jackson, H.P. Freund 2, D.
E. Pershing 3, and V.L. Granatstein 1, Naval Research Laboratory.
1=U. of Maryland, College Park, MD 20742; 2=SAIC, McLean, VA 22102;
3=MRC, Newington, VA 22122.
2Q 22 Adiabatic Trapping In Doubly-Taperred Wigglers.
Scott Hendrickson,
John R. Cary, University of Colorado, Boulder, CO 80309-0391.
2Q 23 Regular and Chaotic Orbits of Electrons in Electric Undulators.
M.
Mochena and R.L. Williams, Florida A&M University.
2Q 24 K-Shell Radiation from Stable Shells and Uniform Fill Z-Pinch Argon
Plasmas.
P. Kepple, J. Davis, and J. Thronhill, Naval Research Lab,
Washington, DC 20375; and F. Cochran and A. Velikovich, Berkeley
Research Associates, Springfield, VA 22150.
2Q 25 Radiative Energetics of an Imploding Krypton Z-Pinch Plasma.
J.
Rogerson, J. Davis, J. Giuliani, Jr. and P. Kepple, Naval Research
Lab., Washington, DC 20375.
2Q 26 Timing Considerations in the K Shell Yield Scaling of Ultra-high
Current Plasma Radiation Sources.
R.E. Terry, J. Davis, Naval
Research Laboratory, Washington, DC 20375.
2Q 27 Spectral and Temperature Measurements of Gas-Puff Z-pinch Plasma.
I.M. Datsko, High current Electronics Institute, Tomsk, Russia.
2Q 28 Implosions, Equilibria and Stability of Rotating Radiating Z-Pinch
Plasmas.
J. Davis, Naval Research Laboratory, Washington, DC; and A.
Velikovich, Berkeley Scholars, Inc. Springfield, VA 22150.
2Q 29 Effect of Line Opacity on the Ratio of Line to Continuum Radiation
Emitted by Z Pinches.
J.P. Apruzese, J.W. Thornhill, K.G. Whitney,
and J. Davis, Plasma Physics Division, Naval Research Laboratory;
N. Loter, Maxwell Laboratories, Inc.; C. Deeney, Physics
International Co.
2Q 30 Hydrodynamics of Multiple Puff Z-Pinch Implosions.
F.L. Cochran,
Berkeley Research Associates, Inc.; Alexander Velikovich, Berkeley
Scholars, Inc.; and J.W. Thornhill, Naval Research Laboratory,
Washington, DC 20375.
2Q 31 Study of Preionization for GIT-4 Inductive Storage Gas-Puff
Implosion.
A.G. Russkih, High Current Electronics Institute, Tomsk,
Russia.
2Q 32 Nonthermal Radiation from Imploding Z-Pinch Plasmas.
J.W. Thornhill,
J. Davis, K. Whitney, J. Giuliani, Naval Research Laboratory,
Washington, DC 20375; and N. Gondarenko, Berkeley Scholars, Inc.
2Q 33 Three-Dimensional PIC Simulatins of Electron Flow in Pulsed-Power
Machines.
J.L. Geary, Jr., Berkeley Research Associates, PO Box 852,
Springfield, VA; S.B. Swanekamp, Science Applications International
Corporation, McLean, VA; and J.M. Grossmann, Naval Research
Laboratory, Washington, Dc.
2Q 34 Production of X-rays by Off-Axis Nonlinear Thomson Scattering of
Intense Laser Pulses from Electron Beams.
S.K. Ride, E. Esarey 1, M.
Baine, University of California, San Diego. 1=Naval Research
Laboratory.
2Q 35 Na-Ne Resonant Photoexcitation X-ray Using Coaxial Double Z-Pinch.
T. Aoki, K. Horioka, Department of Energy, Tokyo Institute of
Technology.
2Q 36 Investigation of Multiple Pulse Irradiation of Slab Targets for
Neon-like X-ray Lasers.
J.C. Moreni, J. Nilsen, A.S. Wan, R. Cauble,
E. Chandler, and L.B. Da Silva, Lawrence Livermore National
Laboratory, University of California, L-59, P.O. Box 808,
Livermore, CA 94550.
2Q 37 Designs for Innershell X-Ray Lasing at $45\AA$ using Modest Energy
Ultrashort Pulse Optical Lasers.
D.C. Eder nd S.J. Moon, Lawrence
Livermore National Laboratory.
2Q 38 Evolution of Current and Temperature in a Capillary Discharge.
T.T.
Stark, B.G. Peterson, A. Reyes, M. Berrondo, G.W. Hart, R.L.
Spencer, Brigham Young University, Provo, UT; E.P. Ivanova, L.N.
Ivanov, Russian Academy of Science, Troitsk, Russia.
2Q 39 Time-Resolved Measurements of Damage to Optical Coatings from Laser-
Plasma X rays.
R.C. Elton 1, J. Grun, P.G. Burkhalter, H.R. Burris
2, B.H. Ripin, D.A. Newman 3, D.M. Bey, C.K. Manka, J.H. Konnert and
J.R. Millard 4, Naval Research Laboratory. 1=Consultant to SFA, Inc.
Landover, MD; 2=Research Support Instr. Alexandria, VA; 3=SFA, Inc.
Landover, MD; 4=Jaycor, Inc. San Diego, CA.
2R 1 1-D Studies of X-mode and P-polarized O-mode Fluctutation
Reflectometry.
A.E. Chou, B.B. Afeyan, B.I. Cohen, and N.C. Luhmann,
Jr., Department of Applied Science, University of California, Davis
and Lawrence Livermore National Laboratory.
2R 2 A 1-D Computational Study of Ultra-short-pulse Reflectometry.
J.K.
Cohen, B.B. Afeyan, and N.C. Luhmann, Jr., Lawrence Livermore
National Laboratory and University of California at Davis.
2R 3 2-D Modelling of Reflectometer Measurements and Tokamak Edge
Turbulence.
G.D. Conway, L. Schott and A. Hirose, Dept. of Physics,
Univ. of Saskatchewan, Canada.
2R 4 Theory of Reflectrometry in Multidimensional Inhomogeneous Plasmas.
N.M. Afeyan, B.B. Afeyan, B.I. Cohen, and E.A. Williams, Lawrence
Livermore National Laboratory.
2R 5 Edge density Profile Measurements on DIII-D Using an AM
Reflectometer.
G.R. Hanson, J.B. Wilgen, E.J. Doyle 1, K.W. Kim 1,
C.L. Rettig 1, E. De la Luna 2, J. Sanchez 2, ORNL. 1=University of
California, Los Angeles, California; 2=Asociacion Euratom-CIEMAT,
Madrid, Spain.
2R 6 Reflectometric Density Profile Measurements on the DIII-D Tokamak.
K.W. Kim, E.J. Doyle, G.R. Hanson 1, W.A. Peebles, N.C. Luhmann, Jr.
2, T.L. Rhodes, C.L. Rettig, and J.B. Wilgen 1, UCLA. 1=Oak Ridge
National Laboratory; 2=University of California, Davis.
2R 7 Development of New Reflectometer Systems for the Core and Divertor
of DIII-D.
E.J. Doyle, T.L. Rhodes, J.L. Doane 1, K.W. Kim, and W.A.
Peebles, UCLA. 1=General Atomics.
2R 8 Ultrashort-Pulse Radar Reflectometry on CCT and TEXT-U.
C.W. Domier,
A.E. Chou, W-M. Zhang, and N.C. Luhmann, Jr. UCD.
2R 9 ECE Imaging Arrays for TEXT-Y.
ZR.P. Hsia, E. Ching, W.R. Geck, C.W.
Domier, and N.C. Luhmann, Jr., UCD.
2R 10 Correlation Reflectometry: Comparison with Langmuir Probes and
Theory.
T.L. Rhodes, E.J. Doyle, W. Gekelman, W.A. Peebles, P.
Pryble, R.J. Taylor, G. Tynan, Institute of Plasma and Fusion
Research, EE Dept., UCLA.
2R 11 AM Reflectometry in Madison Symmetric Torus.
Dmitry Sinitsyn and
Samuel Hokin, Dept. of Physics, Univeristy of Wisconsin-Madison.
2R 12 Multiple Fan Beam Interferometry/Polarimetry on TEXT-U.
W.R. Geck,
R.P. Hsia, X. Qin, J. Liao, C.W. Domier, and N.C. Luhmann, Jr., UCD.
2R 13 Comparison of High Temperature DIII-D ECE Spectra with Calculations
of the Relativistic Dispersion Relation.
M.E. Ausin 1, R.F. Ellis 1,
R.A. James 2, T.C. Luce, R.W. Harvey, General Atomics. 1=University
of Maryand; 2=Lawrence Livermore National Laboratory.
2R 14 Initial ECE Radiometer Electron Temperature Measurements on DIII-D.
G.L. Bell, J.M. Lohr 1, J.B. Wilgen, M.E. Austin 2, C.B. Forest 1,
ORNL. 1=General Atomics, San Diego, California; 2=University of
Maryland.
2R 15 Improved Model for Obtaining Ion Temperature from the C VI 5290
$\AA$ Line.
R.J. Groebner, K.H. Burrell, P. Gohil, H.E. St. John,
and A. Zwicker 1, General Atomics. 1=Oak Ridge National Laboratory.
2R 16 Real-Time Measurement of q Profiles in Strongly Shaped Discharges
Using 16-Channel MSE Data.
B.W. Rice, J.R. Ferron 1, and T.S. Taylor
1, Lawrence Livermore National Laboratory. 1=General Atomics.
2R 17 Development of Helium Neutral Beam Diagnostic for Tokamak Plasmas.
K. Takiyama, T. Oda, K. Mizuno 1, T. Katsuta, and T. Ogawa 2,
Hiroshima University. 1=Univ. of California, Davis/LLNL; 2=Japan
Atomic Energy Research Institute.
2R 18 High-resolution tokamal measurement of the $K\beta$ spectra of
heliumlike argon.
V. Decaux, P. Beiersdorfer, and A. Osterheld,
Lawrence Livermore National Laboratory.
2R 19 Evaluation of LIDAR Thomson Scattering for Advanced Tokamaks.
A.W.
Molvik, E.B. Hooper, R.A. Lerche, D.G. Nilson, M.D. Perry, Lawrence
Livermore National Laboratory.
2R 20 A Laser-Induced Fluorescence Diagnostic for Divertors.
J.M.
McChesney, W.H. Goldstein 1, and K.B. Fournier 1, General Atomics.
1=Lawrence Livermore National Laboratory.
2R 21 Nanosecond, Four Frame TEA $N_2$ Laser Diagnostics.
B. Moosman, V.
Bystritskii, F.J. Wessel, University of California, Irvine.
2R 22 Fundamentals of Lamb-Shift Quench LIF Diagnostics in Plasmas.
R.A.
Stern, and C.G. Boozer, U. of Colorado, Boulder; and J.F. Benage,
Jr., LANL, Los Alamos, NM.
2R 23 Spectroscopic Analysis of a Carbon Seeded Argon Plasma Using Hollow
Cathode Plume Technique.
S.M. Mahajan, R.D. Sexton and C.A.
Ventrice, Tennessee Technological University, Electrical Engineering
Department, Cookeville, Tennessee 38505.
2R 24 Detection of optogalvanic spectra using a driven nonlinear
oscillator.
C.A. Selcher, D. Segal, M.E. Koepke, and W.E. Amatucci,
Physics Department, West Virginia University, Morgantown, WV 26506-
6315. 1=Scientific Dept. 24, Ministry of Defence, P.O. Box 2250,
Haifa 31021, Israel.
2R 25 A High-Resolution Pair Spectrometer for High-Energy Fusion Gamma
Rays.
D.A. Pappas, K.W. Wenzel, and R.D. Petrasso, MIT Plasma Fusion
Center and Nuclear Engineering Dept.
2R 26 Ion Heating Diagnostic Development for PISCES-Upgrade.
J.
Cuthbertson, R. Doerner, R. Lehmer, L. Schmitz, and R.W. Conn,
UC San Diego.
2R 27 Alpha Particle Diagnostics Using Knock-On Ion Tails.
R.K. Fisher,
C.W. Barnes 1, A. Gondhalekar 2, P.B. Parks, J.M. McChesney, A.L.
Roquemore 3, M.N. Rosenbluth 4, General Atomics. 1=Los Alamos
National Laboratory; 2=JET Joint Undertaking; 3=Princeton Plasma
Physics Laboratory; 4=Univeristy of California, San Diego.
2R 28 Concept for a Diamond Staircase Particle Detector for an ITER
Diagnostic.
J.W. Coleman, Plasma Fusion Center, Massachusetts
Institute of Technology.
2R 29 Pressure Measurements in Plasma Working Fluids for Compression by
Liner Implosions.
C.A. Outten, F.M. Lehr, T.J. Englert, and S.E.
Englert, Phillips Laboratory; J.D. Graham, Maxwell Laboratories.
2R 30 Neural Networks for Fusion Data Processing and Control.
G.L. Johns,
ORINCON Corp.
2R 31 "CTMC calculations of partial charge transfer cross sections in
collisions of multi-charged ions with H and Li."
K. Katsonis, G.
Maynard, PAPF, GdR 135 and 918, Laboratoire Phys. des Gaz et
Plasmas, CNRS UA 0733, Univ. Parid Sud, 91405 Orsay.
2S 1 Comparison of High $\beta_p$ Regimes between JET and JT-60U on
Confinement and Fusion Reactivity.
The JET and JT-60 Teams
(presented by S. Ishida 1), JET Joint Undertaking and Japan Atomic
Energy Research Institute. 1=Japan Atomic Energy Research Institute.
2S 2 Toridial Rotation Profile Control Experiment in JT-60U.
T. Fujita,
S. Ide, Y. Kamada, Y. Koide, Y. Kawano, M. Mori, and JT-60U team,
Japan, Atomic Energy Research Institute.
2S 3 Impurity Behavior on JT-60U.
S. Higashijima, A. Sakasai, K. Shimizu,
H. Kubo, Y. Kawano, Y. Koide, T. Sugie, S. Tsuji, and M. Shimada,
Japan Atomic Energy Research Institute.
2S 4 Time and Space-resolved Triton Burnup Measurements on JT-60U.
G.A.
Wurden, R.E. Chrien, Los Alamos National Laboratory; T. Nishitani,
T. Kondoh, M. Hoek, and H. Harano, Japan Atomic Energy Research
Institute.
2S 5 High Performance Plasmas with the JET Pumped Divertor in JET.
R.
Konig for the JET Team, JET Joint Undertaking, Abingdon, Oxon. UK.
2S 6 Comparison of Vertical and Horizontal Target Plate Operation with
the JET Mark I Divertor.
D.J. Campbell, S. Clement, L. Horton, H.
Lingertat, C. Lowry, R. Monk, G. Saibene, A. Taroni, G. Vlases, and
the JET Team, JET Joint Undertaking, Abingdon, UK.
2S 7 The Behaviour of Divertor and Scrape-off layer Parameters in the JET
Pumped Divertor.
S. Davies, B. Altan, S.K. Erents, A. Loarte, G.F.
Matthews, K. McCormick, R.D. Monk, A. Taroni, S.A. Weber, JET Joint
Undertaking, Abingdon, UK.
2S 8 Level of Error Field in the Pumped Divertor Phase of JET.
G.M.
Fishpool, D.J. Campbell, JET.
2S 9 ICRF Heating of Plasma in the New JET Divertor Configurations.
A.C.C. Sips, M. Bures, C. Gormezano, R. Goulding 1, J. Jacquinot, E.
Righi, F. Rimini, D. Start and B. Tubbing, JET Joint Undertaking,
Abingdon, Oxon, OX14 3EA, UK. 1=Oak Ridge National Laboratory, Oak
Ridge, Tennessee 37831.
2S 10 Initial FWCD Results using the JET A2 Antenna Arrays and Experience
with Phased Operation.
R.H. Goulding, G.L. Bell, D.J. Hoffman, P.M.
Ryan, V. Bhatnagar 1, M. Bures 1, J.A. Dobbing 1, B. Fechner 1,
D.F.H. Start 1, T.J. Wade 1, ORNL. 1=JET Joint Undertaking,
Abingdon, Oxon, OX14 3EA, UK.
2S 11 Fast Particle Losses due to TE-modes in JET.
S. Sharapov, L.C.
Appel, D. Borba, T.C. Hender, G.T.A. Huysmans, W. Kerner, S.D.
Pinches, JEt Joint Undertaking, UK.
2S 12 Li-beam Measurements of Edge Electron density and Impurity Profiles
on JET.
P. Breger, D. Summers, A. Pietrzyk, B. Viccoz, J. Vince.
JET Joint Undertaking, Abingdon, OX14 3EA, Oxfordshire, UK.
2S 13 Comparison of Single and Triple Probe Operation with the JET
Divertor Probe Array.
H.Y. Guo, R.D. Monk, G.F. Matthews, A. Loarte,
JET Joint Undertaking, Abingdon, UK.
2S 14 Parametric Dependencies of JET LIDAR Profiles: Comparison of Ohmic,
L- and H-Modes.
B. Schunke 1, K. Imre 2, and K.S. Riedel 2. 1= JET
Joint Undertaking, Abingdon, Oxon, OX14 3EA, UK; 2=New York
University, 251 Mercer St., New York, NY 10012-1185.
2S 15 Helium Transport and Exhaust in the Presence of a Neon Radiating
Boundary with the ALT-II Pump Limiter In TEXTOR.
D.L. Hillis, G.
Mank 1, K.H. Finken 1, H. Euringer 1, U. Samm 1, B. Unterberg 1, M.
R. Wade, J.T. Hogan, A. Post-Zwicker, J.A. Boedo 2, D.S. Gray 2, A.
M. Messien 3, G. van Oost 3, J. Ongena 3, G. Van Wassenhove 3, and
P. Dumortier 3, ORNL. 1=Institut fur Plasmaphysik Forschungszentrum-
KFA Julich, D-5170, FRG; 2=Institute of Plasma and Fusion Research,
Univ. of California, Los Angeles, CA; 3=Associate "Euatom-Belgische
Staat" Ecole Royale Militaire, B 1040 Brussels.
2S 16 Particle confinement measurements in TEXTOR and comparison with 2D
modeling.
D.S. Gray, J.A. Boedo, R.W. Conn, M. Wuttke 1. UC San
Diego. 1=IPP/Forschungszentrum Julich, Germany (association Euratom-
KFA).
2S 17 Structures in the SOL and Edge Plasmas in the TEXTOR Tokamak.
J.A.
Boedo, D. Gray, K.H. Finken 1, G.Mank 1, UC, San Diego.
1=Association EURATOM/KFA, Julich.
2S 18 High Density Operation in FTU With Different Prevailing Impurities.
D. Frigione, L. Pieroni, Associazione EURATOM-ENEA, Frascati, Italy.
2S 19 Fuelling efficiency at very high density in FTU.
V. Zanza, D.
Frigione, Associazione EURATOM-ENEA sulla Fusione CRE ENEA Frascati
(Italy).
2S 20 Soft X Ray Spectrometer and Metallic Impurity Measurements on
Frascati Tokamak Upgrade.
R. Bartiromo, D. Pacella, G. Pizzicaroli,
Associazione EURATOM-ENEA Sulla Fusione CRE ENEA Frascati, CP 65,
00044 Frascati (Roma) Italy.
2S 21 Effect of Argon injection on the high Z impurity generation from the
poloidal inconel limiter in FTU.
L. Pieroni, Associazione EURATOM-
ENEA, Frascati, Italy; I.Condrea, ENEA guest; G. Frannzoni,
Dipartimento di Energetica, Politecnico di Torino, Italy.
2S 22 First Results in Amplitude Modulation Reflectometry on FTU Tokamak.
P. Amadeo, P. Buratti, M. Zerbini, Associazione EURATOM-ENEA Sulla
Fusione CRE Frascati, CP 65, 00044 Frascati (Roma) Italy.
2S 23 Initial Ohmic Confinement Results From TCV.
F. Hofmann, J.B. Lister,
R. Behn, M.J. Dutch, B.P. Duval, B. Joye, X. Llobet, Y. Martin, J.M.
Moret, C. Nieswand, Z.A. Pietrzyk, R.A. Pitts, A. Pochelon, G.
Tonetti, H. Weisen, and TCV Team, CRPP-EPFL, Association Euratom-
Confederation Suisse, Switzerland.
2S 24 MHD activity in Omic, Diverted and Limited L- and H-mode Plasmas in
the TCV tokamak.
H. Weisen, M. Anton, A. Hirt, A. Pochelon, G.
Tonetti and the TCV Team, CRPP, EPFL, Assoc. ERUATOM-Suisse.
2S 25 Ohmic H-modes in TCV.
B.P. Duval, F. Hofmann, A. Pochelon, Z.A.
Pietrzyk, and the TCV Team, CRPP-EPFL Association EURATOM-
Confederation Suisse, CH-1015 Lausanne.
2S 26 Experimental and Modelling Study of the Plasma Dynamic Response in
TCV.
Y. Martin, J.B. Lister, J.-M. Moret, CRPP-EPFL Association
EURATOM-Confederation Suisse, CH-1015 Lausanne.
2T 1 Advanced Tokamak Physics-Status and Prospects.
R.J. Goldston, PPPL;
and the National TPX Physics Team.
2T 2 Tokamak Physics Experiment Design.
John A. Schmidt, and The National
TPX Design Team, PPPL.
2T 3 Status of TPX Diagnostic Development.
S.S. Medley, Princeton
University.
2T 4 Dynamic Evolution of the Negative MAgnetic Shear Configuration.
C.
Kessel, S. Jardin, D. Ignat, Princeton Plasma Physics Lab.
2T 5 Modelling of Phsyics Operating Scenarios in the Tokamak Physics
Experiment (TPX).
P.T. Bonoli and M. Porkolab, MIT Plasma Fusion
Center; V. Fuchs, Hydro Quebec; A.H. Kritz, Lehigh University;
W.M. Nevins, LLNL.
2T 6 Phase Control System for the TPX ICH Antenna Arrays.
P.M. Ryan, D.W.
Swain, R.H. Gouldingn, M.D. Carter, D.J. Hoffman, D.B. Batchelow,
Oak Ridge Natl Lab.
2T 7 TPX Plasma Control Capabilities.
G.H. Neilson 1, J.M. Bialek, P.T.
Bonoli 2, R.H. Bulmer 3, P.H. Edmonds 4, R.J. Goldston, S.C. Jardin,
C.E. Kessel, S.S. Medley, W.M. Nevins 3, M. Porkolab 2, D.J.
Strickler 1, Princeton Plasma Physics Laboratory, Princeton, NJ
08543. 1=ORNL; 2=MIT; 3=LLNL; 4=U. Texas.
2T 8 A Study of Techniques for Steady-State Plasma Position Sensing in
the Tokamak Physics Experiment.
Cris W. Barnes, Kurt F. Schoenberg,
and Glen A. Wurden, Los Alamos National Laboratory.
2T 9 Summary of progress on the TPX Divertor Design.
D.N. Hill, and the
TPX Divertor Design Group, Lawrence Livermore Natonal Laboratory.
2T 10 Pumping and Throughput Calculations for TPX.
D.N. Ruzic, D.R.
Juliano, P.F. Cheng, 103 S. Goodwin Ave., University of Illinois,
Urbana, IL 61801.
2T 11 High power radiative divertor scenario for TPX and ITER.
B.J.
Braams, D.N. Hill 1, D.K. Raevsky, and K.A. Werley 2, Courant
Institute, NYU. 1=Lawrence Livermore National Laboratory; 2=Los
Alamos National Laboratory.
2T 12 The Ignitor Project.
M. Nassi, F. Carpignano, B. Coppi, and The
Ignitor Project Group, ENEA and M.I.T.
2T 13 New Findings on Confinement and Projections for Ignitor.
P.
Detragiache, B. Coppi, M. Nassi, ENEA, Italy and MIT, USA.
2T 14 Operations Plan for Ignitor.
P. Corsasro, M. Nassi, M. Zucchetti,
Politecnico di Torino and ENEA Italy.
2T 15 Updated Ignitor Scenarios.
G. Cenacchi, CRE, ENEA, Bologna, Italy;
A. Airoldi, IFP, CNR, Associazione EURATOM-ENEA-CNR, Milano, Italy.
2T 16 A simple analysis of the power load on the wall of the IGNITOR
tokamak during normal operation.
C. Ferro, Associazione EURATOM-
ENEA, Frascati, Italy; G. Franzoni, R. Zanino, Dipartimento di
Energetica, Politecnico di Torino, Italy.
2T 17 Prototypes Construction in the Ingitor Program.
F. Carpignano, B.
Coppi, M. Nassi, and The Ignitor Project Group., M.I.T. and ENEA.
2T 18 Neutron Diagnostics for Ingitor.
S. Rollet, P. Batistoni, ENEA CRE
Frascati, Via E. Fermi 27, I-00044 Frascati, Italy.
2T 19 Activation Analysis for Ignitor.
M. Zucchetti, P. Corsaro,
Politecnico di Torino, Italy.
2T 20 Safety Analysis for the Ignitor Machine.
A. Carpignano, G. Franzoni,
Politecnico di Torino, Italy; and M.T. Porfiri, ENEA, Italy.
2T 21 Performance of Spherical Tokamak Plasmas.
M.J. Walsh, D. Gates, M.
Gryaznevich, I. Jenkins, R. Martin, C. Ribeiro 1, D.C. Robinson, A.
Sykes, J. Tomas, and H.R. Wilson, Culham Laboratory, Oxon, OX14 3DB,
UK, EURATOM/UKAEA Fusion Association. 1=CNpq/University de Sao
Paulo, Brazil.
2T 22 Plasma Voltages, Flux Consumption, and Neutral Beam Calculations for
START.
R.J. Colchin, J.D. Galambos 1, S.P. Hirshman, J.A. Rome,
ORNL; M. Cox, G. Counsell, M. Graznevich, A. Sykes, M. Walsh,
Culham. 1=Computing Applications Division, Martin Marietta Energy
Systems, Inc.
2T 23 Fluctuation Measurements from the COMPASS-D and START Tokamaks.
D.
Gates, A.W. Morris, S.J. Fielding, M. Valovic, T.C. Hender,
COMPASS-D Team, S.K. Erents, M. Gryaznevich, J. Hugill, A. Sykes,
and the START Team. UKAEA Government Division, Fusion, Culham,
Abingdon, Oxon OX14 3DB UK (UKAEA/EURATOM Fusion Association).
2T 24 H-modes and error-field control in COMPASS-D.
A.W. Morris, S.J.
Fielding, D. Gates, T.C. Hender, M. Valovic, and the COMPASS-D Team,
UKAEA Government Division, Fusion, Culham, Abingdon, Oxon OX14 3DB
UK (UKAEA/EURATOM Fusion Association).
2T 25 National Spherical Tokamak Experiment (NSTX).
J. Robinson, M. Ono,
H.M. Fan, R. Goldston, Y.S. Hwang, S. Jardin, S. Kaye, J. Menard,
N. Pomphrey, Princeton University; M. Peng, Oak Ridge National
Laboratory.
2T 26 Physics Overview of NSTX.
S.M. Kaye, R. Goldston, Y.-S. Hwang, S.
Jardin, C. Kessel, J. Menard, M. Ono, N. Pomphrey, G. Rewoldt,
W. Tang, Princeton University.
2T 27 Enhanced ideal MHD stability and improved advanced reactor
performance in the NSTX Spherical Tokamak.
J. Menard, S. Jardin, S.
Kaye, C. Kessel, M. Ono, Princeton University.
2T 28 Microinstability Studies of Small-Aspect-Ratio Rokamaks.
G. Rewoldt,
W.M. Tang, and S.Kaye, Princeton University.
2T 29 Status and Plan for Low-Aspect-Ratio CDX-U Tokamak.
G. Ludwig 1, W.
Choe, A. Frederiksen 2, R. Heeter, Y.S. Hwang, T.G. Jones, E. Lo,
J. Menard, R. Nazikian, H. Quin, and M. Ono, Princeton University.
1=INPE, Brazil; 2=Univ. of Tromso, Norway.
2T 30 Low Loop Voltage Start-up Experiments in Low-Aspect-Ratio CDX-U
Tokamak.
Y.S. Hwang, T.G. Jones, W. Choe, and M. Ono. Princeton
University.
2T 31 Low-aspect-ratio, Low-$q_a$ Ohmic Operation in CDX-U.
T.G. Jones,
Y.S. Hwang, W. Choe, E. Lo, M. Ono, Princeton University.
2T 32 Study of Electron Ripple Injection on CDX-U.
W. Choe, M. Ono, C.S.
Chang 1, Y.S. Hwang, Princeton University. 1=New York University.
2T 33 A Laser Based Tangential Imaging System for XDC-U.
E. Lo, R.
Nazikian, and the CDX-U Group, Princeton University.
2T 34 Microwave Polarimetry System in the CDX-U Tokamak.
A. Frederiksen 1,
H. Quin, Y.S. Hwang, C.B. Forest 2, and M. Ono, Princeton
University. 1=Univ. of Tromso, Norway; 2=GA.
2T 35 Experimental Study of Ultra-Low Aspect Ratio Tokamak.
M. Yanada, S.
Jardin, and N. Pomphrey, PPPL, Princeton U., NJ; A. Morita, Y. Ono,
and M. Katsurai, U. of Tokyo, Tokyo, Japan.
2T 36 First Results from the Low-Aspect-Ratio MEDUSA Tokamak.
G.D.
Garstka, J. Basken, J.R. Danielson, D. Dettmers, B. Foucher, L.
Kress, B. Lewicki, D. Mayer, M. Springer, K. Tritz, and R.J. Fonck,
University of Wisconsin-Madison.
2T 37 Helicity Injected Spherical Torus Experiment.
M. Nagata, Y.
Kinugasa, M. Nishida, N. Fukumoto, T. Uyama, Faculty of Engineering,
Himeji Institute of Technology.