SESSION 7RV: DYNAMICS OF NON-NEUTRAL PLASMAS

7RV 1 Dynamics of Nonnuetral Plasmas.
Roy W. Gould, California Institute of Technology.

SESSION 7IA: BASIC WAVES

7IA 1 First Experimental Detection of Ion Plasma Waves.
Bruno S. Bauer, Lawrence Livermore National Laboratory.

7IA 2 Spectra of Developed Langmuir Turbulence in a Non-Isothermal Magnetized Plasma.
L.N. Vyacheslavov, Budker Institute, Novosibirsk, Russia.

7IA 3 Velocity-Shear Induced Ion-Cyclotron Turbulence: Laboratory Identification and Space Applications.
M.E. Koepke, West Virginia University.

SESSION 7IB: PLASMA PROCESSING AND ELECTRON BEAMS

7IB 1 Power Deposition in High Density Inductively Coupled Plasma Tools for Semiconductor Processing.
E.F. Jaeger, Oak Ridge National Laboratory.

7IB 2 Dynamic Focusing of a Short, Relativistic Electron Bunch by a Plasma Lens.
G. Hairapetian, UCLA.

7IB 3 Very High-Current Electron-Beam Transport in Long Gas Cells.
T.W.L. Sanford, Sandia National Laboratories.

SESSION 7E: ORAL SESSION: ICF: IMPLOSIONS, STABILITY AND MIX

7E 1 Diagnosis of Pusher-Fuel Mix in Indirectly Driven Nova ICF Capsule Implosions.
T.R. Dittrich, B.A. Hammel, C.J. Keane, R. McEachern, R. E. Turner, S.W. Haan, Lawrence Livermore National Laboratory.

7E 2 Simulations of Spectral Signatures and Images of Core-Shell Mixing in Laser-Driven Implosions.
R. Epstein, J.A. Delettrez, C.P. Verdon, D. Shvarts, and B. Yaakobi, LLE, U. of Rochester.

7E 3 A Mix Model in LILAC for the Linear and Weakly Nonlinear Regime of the Rayleigh-Taylor Instability.
J.A. Delettrez, D.K. Bradley, and C.P. Verdon, LLE, U. of Rochester.

7E 4 2D Models of Emission Line Ratios in ICF Target Implosions.
S.H. Langer, C.J. Keane, H.A. Scott, Lawrence Livermore National Laboratory.

7E 5 Two-Dimensional Calculations of Instability Growth and Mode Coupling in Convergent Geometry.
J.B. Beck, N.M. Hoffman, Los Alamos National Laboratory.

7E 6 Nonlinear Multimode Calculations of Hydrodynamic Stability in ICF Implosions.
N.M. Hoffman, C.K. Choi, J.B. Beck, Los Alamos National Laboratory.

7E 7 Hydrodynamic Instability of NIF Capsules with Beryllium Ablators.
D.C. Wilson, N.M. Hoffman, W.J. Krauser, Los Alamos National Laboratory.

7E 8 Integrated Ignition Calculations for Indirectly Driven Targets.
William J. Krauser, Bernhard H. Wilde, D.C. Wilson, Los Alamos National Laboratory.

7E 9 Hot Spark Structure of Laser-Imploded Core Observed by Using a 2- Dimensional X-Ray Imaging with 10-ps Timporal Resolution.
H. Shiraga, M. Heya, N. Miyanaga, K. Nishihara, K.A. Tanaka, Y. Kato, T. Yamanaka, and S. Nakai, Institute of Laser Engineering, Osaka University, Japan.

7E 10 Simulation of Nonuniformities in Pellet Implosions.
J.H. Gardner, J. P. Dahlburg, S.E. Bodner, A.J. Schmitt, & D. Colombant, Naval Research Laboratory.SESSION 7F, THURSDAY MORNING, 9:30

SESSION 7F: TFTR

7F 1 Optimizing the DT Fusion Power in TFTR.
M.G. Bell, R.V. Budny, J.D. Strachan, D. Mansfield, D.R. Mikkelsen, Princeton University.

7F 2 Continued TFTR Wall Conditioning Experiments using LI Pellets: Deuterium/Tritium Plasmas and Limiter H-Modes.
D.K. Mansfield, J.D. Strachan, M.G. Bell, C.E. Bush and S. Sabbagh (Columbia) and J. Terry, E. Marmar, J. Snipes (MIT).

7F 3 Observation of KBM-like Modes in TFTR DD and DT Experiments.
Z. Chang 1, E.D. Fredrickson, R.V. Budny, J.D. Callen 1, A.Janos, K.M. McGuire, R. Nazikian, E. Mazzucato, G. Taylor and TFTR Team, Princeton University. 1=University of Wisconsin.

7F 4 Deuterium-Tritium Plasmas at High Poloidal Beta in TFTR.
S.A. Sabbagh, M.E. Mauel, and G.A. Navratil, Columbia University; S.H. Batha, M.G. Bell, R.V. Budny, C.E. Bush, F.M. Levinton, K.M. McGuire, D.K. Owens, H.K. Park, M.C. Zarnstorff, S.J. Zweben, and the TFTR Group, Princeton Plasma Physics Laboratory; J. Kesner, MIT.

7F 5 Tritium Transport Experiments on TFTR During D-T Operation.
P.C. Efthimion, L.C. Johnson, J.D. Strachan, E.J. Synakowski, M. Zarnstorff, C. Barnes 1, M. Loughlin 2, G. Rewoldt, and W.M. Tang, Princeton University. 1=Los Alamos National Lab, Los ALamos, NM; 2=JET, U.K.

7F 6 ICRF Heating of DT Plasmas in TFTR.
J.R. Wilson, D. Darrow, J.C. Hosea, R. Majeski, C.K. Phillips, J.H. Rogers, J.E. Stevens, G. Schilling, G. Taylor, and the TFTR Group,Princeton University; M. Murakami, D. Rasmussen, ORNL.

7F 7 Modulated ICRF Heating and Transport in DT TFTR Plasmas.
M. Murakami, A.C. England, G.R. Hanson, E.F. Jaeger, D. A. Rasmussen, J.B. Wilgen, ORNL; M.G. Bell, R. Budny, D. Darrow, E. Fredrickson, J.C. Hosea, R.Majeski, H. Park, C.K. Phillips, J.H. Rogers, G. Schilling, S.C. Scott, J.E. Stevens, G. Taylor, J.R. Wilson, M.C. Zarnstorff, PPPL.

7F 8 Alpha Loss in TFTR DT Experiments.
S.J. Zweben, D.S. Darrow, H.W. Herrmann, R.V. Budny, C.S. Chang 1, M.H. Redi, J. Schivell, S.D. Scott, K. Tobita 2, PPPL. 1=New York University, New York; 2=JAERI, Naka, Japan.

7F 9 ICRF-Induced Loss of Alpha Particles and RF Tail Ion Loss from TFTR Plasmas.
D.S. Darrow, H.W. Herrmann, M. Holt, R. Majeski, C.K. Phillips, J. Rogers, G. Schilling, G. Taylor, J.R. Wilson, S.J. Zweben, Princeton Plasma Physics Lab.; C.S. Chang, NYU; E.F. Jaeger, M. Murakami, ORNL.

7F 10 $\alpha$-heating in TFTR D-T plasmas.
M.C. Zarnstorff, R. Budny, D. McCune, S. Scott, and the TFTR Group, Princeton Plasma Physics Laboratory.

7F 11 Plasma Turbulence and Associated Transport in TFTR DD and DT Discharges.
R.J. Fonck 1, R.D. Durst 1, H. Evensen 1, J.S. Kim 1, and S.F. Paul 2. 1=University of Wisconsin-Madison; 2= Princeton University.

7F 12 Future Directions for TFTR D-T Experiments.
R.J. Hawryluk and TFTR Group, Plasma Physics Laboratory, Princeton, New Jersey.

SESSION 7P: POSTER SESSION: GENERAL MHD AND FLUID EQUILIBRIUM AND STABILITY

7P 1 Plasma Dynamics with Electron Inertia Effects: Stability in the Liapunov Sense.
B.K. Shivamoggi, University of Central Florida, Orlando; and T.J. Schep, FOM Instituut voor Plasmafysica Rijnhuizen, Nieuwegein, The Netherlands.

7P 2 Rotating Magnetohydrodynamics I.
D. Montgomery and X. Shan, Dartmouth College, Hanover, NH 03755-3528.

7P 3 Rotating Magnetohydrodynamics II.
X. Shan and D. Montgomery, Dartmouth College.

7P 4 Ideal MHD Stability Properties of Small Aspect Ratio Tokamaks.
L.A. Charlton, J.-N. Leboeuf and B.A. Carreras, Oak Ridge National Laboratory, Oak Ridge, Tennessee 37831-8058; and A.A. Martynov, Keldysh Institute of Applied Mathematics, Russia.

7P 5 Stability of Anisotropic Plasmas in High Beta Tokamaks.
M.W. Phillips and M.H. Hughes, Northrop Grumman Corporation.

7P 6 Alpha Particle Effects on Resistive MHD Modes in Toroidal Geometry.
Dun-In Choi, Kwang-Il You, Korea Advanced Institute of Science and Technology; and J.Y. Kim, Kyoto Univ. Japan.

7P 7 Pseudo-MHD Ballooning Modes in Tokamaks.
J.D. Callen and C.C. Hegna, University of Wisconsin-Madison.

7P 8 Study of Magnetohydrodynamic Instibilities Excited by Energetic Particles in Tokamaks.
R.A. Santoro and L. Chen, University of California, Irvine.

7P 9 On Unified Description of Kinetic Ballooning Modes and Beta-Induced Alfven Eigenmodes in Tokamaks.
Liu Chen, R.A. Santoro, and Fulvio Zonca 1, University of California at Irvine. 1=Associazione Euratom- ENEA, Frascati, Italy.

7P 10 Theory of Toroidal Alfven Modes excited by energetic particles in tokamaks.
Fulvio Zonca and Liu Chen 1, Associazione Eruatom-ENEA. 1=University of California at Irvine.

7P 11 Kinetic theory of ballooning modes.
L.-J. Zheng and M. Tessarotto, Trieste University.

7P 12 External Kink Modes in a Cylindrical Resistive Plasma with a Resistive Wall.
Hilary J. Oliver, A.H. Reiman, D.A. Monticello, Princeton University.

7P 13 Nonlinear Saturation of Toroidal Alfven Eigenmodes via Ion Compton Scattering.
T.S. Hahm and L. Chen 1, Princeton University. 1=University of California at Irvine.

7P 14 Stability of Resistive Wall Kink Modes in a Toroidally Rotating Tokamak.
J.P. Freidberg, MIT Plasma Fusion Center; R. Betti, University of Rochester.

7P 15 Theory of the Beta-Induced Alfven Eigenmode.
R. Betti, LLE, U. of Rochester; H.L. Berk, Inst. for Fusion Studies, Univ. of Texas at Austin; J.P. Freidberg, MIT.

7P 16 Iso-topological magnetic field diffusion.
R.T. Ratt, A.V. Gruzinov, P.H. Diamond, Physics Department, University of California, San Diego, La Jolla, CA 92093-0319.

7P 17 MHD Stability of High-Beta Tokamak Equilibria.
Robert G. Kleva and J.F. Drake, Institute of Plasma Research, University of Maryland, College Park, MD 20742-3511.

7P 18 Instabilities Observed in Magnetically Imploded Cylindrical and Quasispherical Solid Liners.
E.L. Rudin, D.E. Bell, J.H. Degnan, S. E. Englert, F.M. Lehr, C.A. Outten, D.W. Price, Phillips Laboratory; S.K. Coffey, Physical Sciences, Inc.; J.D. Graham, Maxwell Laboratories, Inc.

7P 19 A Stable High $\beta\$ Tokamak?
S.C. Cowley and M. Artun. Uiversity of California, Los Angeles.

7P 20 The Equilibrium and Particle Orbits of High-$beta _{P}$, Finite Aspect Ratio Tokamaks.
S.C. Hsu 1, M. Artun, and S.C. Cowley, Uiversity of California, Los Angeles. 1=Princeton Plasma Physics Laboratory.

7P 21 Considerations of Microinstabilities in High-$beta$ Plasmas.
M. Artun and S.C. Cowley, Uiversity of California, Los Angeles.

7P 22 Effects of Parallel Transport on the External Kink Mode in Tokamaks.
R.A. Gerwin and J.M. Finn, Los Alamos National Laboratory, Los Alamos, NM.

7P 23 Resistive Wall Stabilization of External Kinks and Tearing Modes.
John M. Finn, Los Alamos National Laboratory, Los Alamos, NM 87545.

7P 24 DCON: The Direct Criterion of Newcomb for the Stability of an Axisymmetric Toroidal Plasma.
A.H. Glasser, Los Alamos National Laboratory.

7P 25 Improved Stability Condition for Rotating Plasma.
H. Holties and E. Hameiri, and FOM-Instituut voor Plasmafysica, The Netherlands, and Courant Institute-NYU.

7P 26 Transformations on the Magnetic Surface.
D. Subbarao, R. Uma and H. Singh, Centre for Energy Studies and Department of Physics, Indian Institute of Technology, Delhi, New Nelhi 110016.

7P 27 Vertical Stability and Shape Control Simulations Using CORSICA.
L.D. Pearlstein, T.B. Kaiser, J.A. Crotinger, S.W. Haney and L.L. LoDestro. Lawrence Livermore National Laboratory.

7P 28 Relabeling symmetry and Ertel's theorem.
Nikhil Padhye and P.J. Morrison, Institute for Fusion Studies and Department of Physics, The University of Texas at Austin, Austin, TX 78712.

7P 29 Eliminating Locked Mode Instabilities in Tokamaks with Correction Coils.
James D. Hanson, Auburn University.

7P 30 Using Alpha Particles to Spin Up a Tokamak Reactor.
F.L. Hinton, M.N. Rosenbluth 1, General Atomics. 1=University of California, San Diego.

7P 31 Thermodynamic aspects of fliud dynamics and covariant Onsager symmetry.
J.M. Greene 1 and P.J. Morrison, Institute for Fusion Studies and Department of Physics, The University of Texas at Austin, Austin, TX 78712. 1=General Atomics.

7P 32 2D Equilibria of Arbitrary Shaped Plasmas.
V.I. Ilgisonis, Russian Research Centre "Kurchatov Institute," 123182 Moscow, Russia.

7P 33 Lyapunov Stability of Some Toroidal Plasma Equilibria.
V.P. Pastukhov and V.I. Ilgisonis, Russian Research Centre "Kurchatov Institute," 123182 Moscow, Russia.

SESSION 7Q: GYROFLUID, KINETIC THEORY, AND SIMULATIONS

7Q 1 $\delta f$ Monte Carlo Code.
M. Sasinowski, A.H. Boozer, William & Mary, VA.

7Q 2 Gyrokinetic MDH Hybrid Simulation of TAE Modes.
G.Y. Fu and W. Park, Princeton University.

7Q 3 Linear Power Transfer of Energetic Particles to Toroidal Alfven Eigenmodes.
H. Vernon Wong and H.L. Berk, Institute for Fusion Studies, The University of Texas at Austin.

7Q 4 Numerical Simulation of the Wave Energy Bursts in a Driven System.
M.S. Pekker, H.L. Berk, and B.N. Breizman, Institute for Fusion Studies, The University of Texas at Austin.

7Q 5 Simulation of Resonant Coupling of Energetic Particles to Toroidal Alfven Eigenmodes.
B.N. Breizman, H.V. Wong, H.L. Berk, M. Pekker, and A.Aydemir, Institute for Fusion Studies, The University of Texas at Austin.

7Q 6 Study of Sawtooth Stabilization in TFTR.
Yi Zhao and R.B. White, Princeton University.

7Q 7 Self-consistent study of the alpha-particle-driven TAE mode.
Yanlin Wu and R.B. White, Princeton University.

7Q 8 Sawtooth Stabilization and Ripple Induced Alpha Particle Loss in ITER.
R.B. White, Yanlin Wu, Yi Zhao, Princeton University.

7Q 9 Monte Carlo Collision Operator for nonlinear $\delta f$ weighting schemes.
M. Tessarotto 1, R.B. White 2, and L.J. Zheng 1. 1=Trieste University; 2=Princeton University.

7Q 10 A Pseudospectral Method Solution of the Moments of the Vaslov Equation.
Russell Cottam, NYMA, Inc. 2001 Aerospace Pky., Brookpark, Ohio 44142.

7Q 11 Radial and Poloidal Electric Field Effects on Particle Neoclassical Trajectories in a Tokamak.
L. Gauthier 1, CCFM, Varennes, Quebec, J3X 1S1; S.I. Krasheninnikov 2, PFC, MIT, Cambridge, MA, USA. 1=Hydro-Quebec, Varennes (Quebec) Canada; 2=I.V. Kurchatov Institute of Atomic Energy, Moscow, Russia.

7Q 12 Eta-i Driven Kinetic Ballooning Mode in Tokamaks.
L. Zhang, M. Elia, A. Hirose, Univ. of Sask., Saskatoon, Canada.

7Q 13 Ion Acoustic Ballooning Mode in Tokamaks.
A. Hirose, Univ. of Sask., Saskatoon, Canada.

7Q 14 Renormalized Dissipation in Plasmas with Finite Collisionality.
D. Carati and S.E. Paker, Universite Libre de Bruxelles, Belgium; Princeton Plasma Physics Laboratory.

7Q 15 Kinetic theory of ion acoustic waves.
J. Myatt, V. Yu. Bychenkov 1, W. Rozmus, and V.T. Tikhonchuk 1, Department of Physics, University of Alberta, Edmonton, Canada. 1=P.N. Lebedev Physics Institute, Russian Academy of Sciences, Moscow, Russia.

7Q 16 Kinetic Theory of Stringer Spin-up.
T.M. Antonsen,Jr., A.B. Hassam, A.A. Galeev, C.S. Lin, S. Novakovski, and R.Z. Sagdeev, Institute for Plasma Research, University of Maryland, College Park, MD.

7Q 17 Effect of Collisions on Alpha-Alfven Waves, Including Generalized Resistivity.
C.L. Hedrick, J.-N. Leboeuf, and D.A. Spong, ORNL.

7Q 18 Gyrofluid Models of Fast Ion-Driven Shear Alfven Instabilities in Tokamaks and Stellerators.
D.A. Spong, C.L. Hedrick, B.A. Carreras, ORNL.

7Q 19 Characteristics of Dissipative Trapped Electron Mode Turbulence Calculated from a Gyro-Landau Fluid Model.
K.L. Sidikman, C.L. Hedrick, J.-N. Leboeuf, V.E. Lynch, ORNL.

7Q 20 Electron Dynamics Models in Toroidal Gyrokinetic Particle Simulations.
R.D. Sydora, University of California, Los Angeles.

7Q 21 Nonlinear gyrokinetic Vlasov equation for toroidally rotating axisymmetric tokamaks.
Alain J. Brizard, University of California at Berkeley.

7Q 22 Ion Temperature Gradient Driven Modes in Plasmas with Negative Impurity Density Gradient.
J.Q. Dong, W. Dorland, W. Horton, G.W. Hammett 1, M.A. Beer 1, Institute for Fusion Studies. 1=Princeton Plasma Physics Laboratory.

7Q 23 Nonlinear Toroidal Gyrofliud Simulations with Trapped Electrons.
M.A. Beer and G.W. Hammett, Princeton University.

7Q 24 Kinetic Closure for Fluid Equations with Finite Larmor Radius Effects.
I.O. Pogutse 1, A.I. Smolyakov, A. Hirose, Univ. of Saskatchewan, Canada. 1=Russian Scientific Center "Kurchatov Institute."

7Q 25 Average Theory of Motion in Asymmetric Tori with Finite Rotational Transform.
Sveta G. Shasharina and John R. Cary, University of Colorado, Boulder, CO 80309-0391.

7Q 26 3-Dimensional Simulations of the Parallel Velocity Shear Instability.
D.R. McCarthy, Southeast Louisiana University, Hammond, Louisiana 70402; P.N. Guzdar and J.F. Drake, Institute for Plasma Research, University of Maryland, College Park, MD 20742-3511.

7Q 27 Symbolic Analysis of Turbulent Plasma Fluctuations.
A.B. Rechester, Institute of Nonlinear Science Applications; T.E. Evans, GA; R.S. Granetz, MIT; and R.B. White, Princeton Plasma Physics Lab.

SESSION 7R: POSTER SESSION: DIVERTORS

7R 1 Divertor Radiation in JET.
R. Reichle, N.A.C. Gottardi and R.M. Giannella, JET Joint Undertaking, Abingdon, UK.

7R 2 Impurity Transport in PISCES-A Gaseous Divertor Simulations.
L. Blush, L. Schmitz, B. Merriman, R. Lehmer, R.W. Conn 1, Institute of Plasma and Fusion Research, UCLA. 1=School of Engineering, University of California, San Diego.

7R 3 Neutral Gas Dynamics in a Simulated Gas Target Divertor.
A. Grossman, L. Schmitz, R.W. Conn, IPFR, University of California; D.P. Stotler, PPPL.

7R 4 Modelling of a High Pressure Gas Target Divertor.
B.J. Lee, F. Najmabadi, and L. Schmitz, University of California, San Diego.

7R 5 Gas Target Experiments in High Heat Flux Plasma of The TPD-I Device.
N. Ohno, S. Masuzaki, S. Mori, N. Ezumi, M. Takagi, and S. Takamura, Nagoya University.

7R 6 Control of Reflected Neutral Particle Energy by Divertor Biasing for Selective Helium-Ash Pumping using Divertor Simulator Co-NAGDIS.
T. Kuwabara, M. Kojima, N. Ohno, Y. Uesugi, S. Takamura, Y. Yamamura, Nagoya Univ. and Okayama Univ. of Science.

7R 7 Formation of Oscillating Electric Filed by AC Divertor Biasing and its Effect on Particle Transport.
Y. Uesugi, H. Misina, Y. Suzuki and S. Takamura, Nagoya University.

7R 8 Thermal Front Analysis of Detached Divertors and Marfes.
I.H. Hutchinson, MIT Plasma Fusion Center.

7R 9 Equilibrium and Stability of Marfes and Detached Plasmas.
J. Kesner, J.P. Freidberg, B. LaBombard, MIT Plasma Fusion Center.

7R 10 On Radiative Divertor Detachment.
N.S. Krasheninnikova, S.I. Krasheninnikov 1, D.J. Sigmar, MIT Plasma Fusion Center. 1=Kurchatov Institute, Moscow, Russia.

7R 11 2D Modeling of Super Dense Divertor Plasma with Navier-Stokes Neutrals.
D.J. Sigmar, S.I. Krasheninnikov 1, MIT Plasma Fusion Center; D.Knoll, P.R. McHugh, Idaho National Engineering Laboratory. 1=Kurchatov Institute, Moscow, Russia.

7R 12 Diamagnetic and E x B Drifts and Divertor Plasma Detachment.
S.I. Krasheninnikov 1, D.J. Sigmar, MIT Plasma Fusion Center; P.N. Yushmanov, Kurchatov Institute, Moscow, Russia. 1=Kurchatov Institute, Moscow, Russia.

7R 13 The role of edge turbulence in detached divertor plasmas.
F.Y. Gang, S.I. Krasheninnikov, and D.J. Sigmar, MIT Plasma Fusion Center, Cambridge, MA 02139.

7R 14 Aspects of Computational Thermally Collapsed States and Time Dependent Behavior.
G.G. Craddock, A.E. Koniges, J.L. Milovich, and T.D. Rognlein, Lawrence Livermore National Laboratory.

7R 15 Adaptive Grid Algorithm Development for Divertor Tokamak Plasmas.
J.L. Milovich, D. Marcus, A. Koniges, and J. Bell, Lawrence Livermore National Laboratory.

7R 16 On the stability of impurity radiation losses in Tokamak scrape-off layer.
D.Kh. Morozov 1, T.K. Soboleva 1, Instituto de Ciencias Nucleares, UNAM, Mexico; S.I. Krasheninnikov 1, D.J. Sigmar, Plasma Fusion Center, MIY, USA. 1=1=Kurchatov Institute of Atomic Energy, Moscow, Russia.

7R 17 Fluid Simulations of an ITER Gas Target Divertor with Impurity Radiative Cooling.
L. Schmitz, B. Merriman, A. Grossman, L. Blush, R. Lehmer, F. Najmabadi, and R.W. Conn, Institute of Plasma and Fusion Research, University of California, Los Angeles.

7R 18 2-D Fluid Modeling of ITER Divertor Scenarios.
D.A. Knoll, P.R. McHugh, Idaho National Engineering Laboratory; S.I. Krasheninnikov and D.J. Sigmar, MIT Plasma Fusion Center.

7R 19 Anistropy in Neutral Atom Transport with Strong Plasma Flow.
W.M. Stacey, T.M. Evans, E.W. Thomas, Georgia Tech.

7R 20 Asymptotic Derivation of the Diffusion Equation for Neutral Atom Transport.
Anil K. Prinja, University of New Mexico.

7R 21 On Plasma and Neutral Gas Flows in Tokamak Divertor.
T.K. Soboleva 1 3, J.J.E. Herrera 1, J.J. Martinell 1, S.I. Krasheninnikov 1 3, D.J. Sigmar 2. 1=Instituto de Ciences Nucleares, UNAM, Mexico, D.F. Mexico; 2=Plasma Fusion Center, MIT, Cambridge, USA; RSC Kurchatov Institute, Moscow, Russia.

7R 22 SOL Turbulence and SOL Structure in L and H Modes.
R.H. Cohen and X.Q. Xu, LLNL.

7R 23 Reduced Impurity Flow Modeling of the Scrape-Off Plasma.
S.P. Hirshman, W.A. Houlberg, S.E. Attenberger, ORNL; S.I. Krasheninnikov, D.J. Sigmar, MIT; D. Knoll, INEL.

7R 24 Magnetohydrodynamic Gas Blanket Divertor for ZTokamaks.
M. Tekula, MRAT; and L. Bromberg, MIT Plasma Fusion Center.

7R 25 Effect of High MN Perturbations on Heat Deposition Pattern on Divertor Plates using Maps.
Halima Ali and Alkesh Punjabi, Hampton University, Hampton, VA 23668; and Allen Boozer, College of William and Mary, Williamsburg, VA. 23185 and Max Planck Institute for Plasma Physics, Garching, Germany.

7R 26 MHD Ballooning Stability Limit for Scrape-Off layer Thickness.
Y.-K.M. Peng and C.L. Hedrick, Oak Ridge National Laboratory; K. Erents, D. Goodall, J. Hugill, and A. Sykes, United Kingdom Atomic Energy Authority Government Division-Fusion.

7R 27 Mode Structure in the Presence of an X-Point.
N. Mattor, R.H. Cohen, and X. Q. Xu, LLNL.

7R 28 A Two-Dimensional Kinetic Model of the Scrape-Off Layer of a Diverted Plasma with a Private Flux Region.
Peter J. Catto, MIT Plasma Fusion Center; J. W. Connor, UKAEA, Government Division, Fusion, Culham, Abingdon, Oxfordshire, OX14 3DB, UK.

7R 29 A K-$\epsilon$ Approach to Divertor Modeling.
L. Vahala, Old Dominion University; G. Vahala, William & Mary; J.H. Morrison, AS&M, Inc.; S. Krasheninnikov, MIT.

7R 30 Singular Surfaces in the Open Field Line Region of a Nonaxisymmetric Poloidal Divertor.
A. Reiman, Princeton University.

7R 31 Coupled Core-Edge Nonlinear Multi-variable Transport Codes.
A. Tarditi, R.h. Cohen, J.A. Crotinger, S.W. Haney, T.D. Rognlien, G.R. Smith, LLNL.

7R 32 Simulation Study of Tokamak Divertor Plasma using 2D Fluid Code.
T. Nakamura, R&D Center, Toshiba Corporation.

7R 33 Divertor Fluid-Simulations with Nonorthogonal Meshes.
T.D. Rognien, M.E. Rensink, and G.R. Smith, Lawrence Livermore National Laboratory; D.A. Knoll, Idaho National Eng. Lab.

7R 34 Impurity-Transport Modelling in the Tokamak Scrape-Off Layer with the UEDGE Code.
G.R. Smith, M.E. Rensink, and T.D. Rognien, Lawrence Livermore National Laboratory; D.A. Knoll, Idaho National Eng. Lab.

7R 35 Fokker-Planck Simulations of Parallel Electron Transport in the Scrape-Off Layer.
K. Kupfer 1, R.W. Harvey, O. Sauter 2, G.M. Staebler, General Atomics. 1=ORISE Postdoctoral Fellow; 2=CRPP/EPFL, Lausanne.

7R 36 Computational Studies of Divertor Plasma Detachment Using A One- Dimensional Model.
R.A. Vesey and D.E. Post 1, Princeton Plasma Physics Laboratory. 1=ITER Joint Central Team, San Diego, CA.

7R 37 Method for coupling a Monte Carlo neutrals code to a plasma code.
C.F.F. Karney and D.P. Stotler, Princeton University.

7R 38 Hybrid Simulation of High-Recycling Divertors.
Hui Long and C.F.F. Karney, Princeton University.

SESSION 7S: POSTER SESSION: SPACE AND ASTROPHYSICAL PLASMAS - II

7S 1 Global Dynamics of Magnetic Flux Tubes in the Sun.
N. Petviashvili and T. Tajima, Institute for Fusion Studies, The University of Texas at Austin.

7S 2 Collapse of a Twisted Magneitc Flux Tube.
Y.T. Lau, Institute for Plasma Research, University of Maryland, College Park, MD 20742 (YTLAY@glue.umd.edu); and J.M. Finn, Group T-15, PO BOx 1663, MS B217, Los Alamos National Lab., Los Alamos, NM 87545.

7S 3 Turbulent Transport of Momentum in a Weakly Magnetized Magnetofluid.
P. Bezhukhov, P.H. Diamond, A.V. Gurzinov, Physics Department, University of California, San Diego, La Jolla, A 92093-0319.

7S 4 Stimulated Raman Scattering Effects on Photon Flux and Neutrino Generation in the Solar Interior.
V.N. Tsytovich 1, and V. Stefan, Tesla Laboratories, Inc., La Jolla, CA; and R. Bingham, Rutherford Appleton Laboratory, Chilton, Didcot, Oxon, UK. 1=General Physics Institute, Russian Academy of Sciences, Moscow, Russia.

7S 5 Time-Dependent Modeling of the Global Structure of the Heliosphere.
P.C. Liewer, Jet Propulsion Laboratory; Steve Roy Karmesin, California Institute; and J.U. Brackbill, Los Alamos Scientific Laboratory.

7S 6 A closure relationship for collisionless solar wind electrons.
E.E. Scime, S.P. Gary, J.L. Phillips, Los Alamos National Laboratory.

7S 7 Nonlinear Dynamics of Alfven Waves in the Solar Wind Plasma.
M.V. Medvedev, P.H. Diamond, Physics Department, University of California, San Diego, La Jolla, A 92093-0319.

7S 8 The Evolution of Plasma Turbulence in the Solar Wind from 10 to 50 Solar Radii.
S.R. Spangler and T. Sakurai, U. of Iowa.

7S 9 Nonlinear Processes in Type III Solar Bursts: Theoretical Constraints versus Observational Data.
P.A. Robinson, University of Sydney, Australia; and Iver H. Cairns, University of Iowa.

7S 10 Langmuir Wave Decay Versus Scattering off Thermal Ions.
Iver H. Cairns, University of Iowa.

7S 11 Excitation and nonlinear dynamics of MHD waves near planetary bow shocks.
V.I. Shevchenko, V.L. Galinsky, S.K. Ride, M. Baine, CalSpace Institute, University of California, San Diego, La Jolla, CA 92093-0407.

7S 12 Nonlinear evolution of the firehose instability: saturational amplitudes and spectral transformation.
K.B. Quest and V.D. Shapiro, ECE Department, California Space Institute, University of California, San Diego, La Jolla, CA 92093-0407.

7S 13 Ion acceleration at quasiperpendicular shocks.
M.A. Lee, Physics Department, University of New Hampshire, Durham, NH 03824; V.D. Shapiro, Physics Department, University of California, San Diego, La Jolla, CA 92093-0319; and R.Z. Sagdeev, Physics Department, University of Maryland, College Park, MD 20742-3511.

7S 14 On the interaction between the shocked solar wind and planetary ions in the dayside mantle of Venus.
K. Szego, Hungarian Institute for Physics, POB 49, Budapest 114; V.D. Shapiro and S.K. Ride, Physics Department, University of California, San Diego, La Jolla, CA 92093- 0319; A.F. Nagy, Space Physics Research Laboratory, University of Michigan, Ann Arbor, MI 48109.

7S 15 Thermal Instability in the inner Coma of a Comet.
A.S. Sharma 1, The University of Maryland, Department of Astronomy, College Park, Maryland 20742. 1=In collaboration with G. Milikh, The Univeristy of Maryland, Department of Astronomy, College Park, Maryalnd 20742.

7S 16 MHD Theory for the Magnetosheath.
C.L. Grabbe, Physics and Astronomy Dept., University of Iowa, Iowa City, IA 52242.

7S 17 One- and Two-Dimensional Hybrid Simulations of Tangential Discontinues.
A.S. Lipatov, A.S. Sharma, and K. Papadopoulos, The University of Maryland, Department of Astronomy, College Park, Maryland 20742.

7S 18 Diffusion at the Magnetopause.
N. Omidi, UCSD; D. Winske, Los Alamos Natl. Lab.

7S 19 Boundary Conditions for the Low-Latitude Boundary Layer in the Magnetosphere.
E. Hameiri, New York University.

7S 20 Nonlinear Dynamics of Standing Shear Alfven Waves.
R. Rankin, P. Frycz, V.T. Tikhonchuk 1, and J.C. Samson, Canadian Network for Space Research, Department of Physics, University of Alberta, Edmonton, Canada. 1-P.N. Lebedev Physics Institute, Moscow, Russia.

7S 21 New Aspects of Megnetospheric Plasma Maser Dynamics.
P.A. Bespalov 1 and V. Stefan, Tesla Laboratories, Inc., La Jolla, CA. 1=Institute of Applied Physics, Nizhny Novgorod, Russia.

7S 22 Predictability of the Magnetospheric Activity and its Implications.
J.A. Valdivia, The Univeristy of Maryland, Department of Physics, College Park, Maryland 20742; A.S. Sharma and K. Papadopoulos, The University of Maryland, Department of Astronomy, College Park, Maryland 20742.

7S 23 A Finite $\beta\$, Kinetic Equilibrium Model of the PSBL-Lobe Interface.
D.L. Holland, P.W. Valek and A. Starkey, Illinois State University, Department of Physics.

7S 24 The Anomalous Resistivity Driven Tearing Process for Substorm Onsets.
A.K. Sundaram and D.H. Fairfield, NASA Goddard Space Flight Center, Greenbelt, MD 20771.

7S 25 A Theoretical Model of the Van Allen Hyupothesis.
Mark Rader and Igor Alexeff, ECE, Univeristy of TN, Knoxville, 37996-2100.

7S 26 Anomalous Scattering and Absorption of Neutrinos in Dense Plasmas.
J.J. Su 1, H.A. Bethe 4, R. Bingham 2, J.M. Dawson 3, and V.N. Tsytovich 1. 1=National Central University, Taiwan; 2=Rutherford Appleton Lab., UK; 3=University of California, Los Angeles, USA; 4=Cornell University, USA.

7S 27 Electron-Neutrino Phase Separation Instability.
C. Lai and T. Tajima, Institute for Fusion Studies and Department of Physics, The University of Texas at Austin.

7S 28 Relativistic Magnetized Plasma Equilibria.
G.M. Tarkenton and T. Tajima, University of Texas at Austin.

7S 29 Cross-Over Effect In Some Magnetic Stars, A Zeeman-Doppler Phenomenon Engendered By Radial Pulsations.
Keith L. McDonald, PO Box 2433, Salt Lake City, UT.

THURSDAY AFTERNOON

SESSION 8IA: RF HEATING AND CURRENT DRIVE

8IA 1 ICRF Heating and Current Drive in Deuterium-Tritium Plasmas.
C.K. Phillips, Princeton Plasma Physics Laboratory.

8IA 2 Alfven Wave Current Drive Experiments in the Phaedrus-T Tokamak.
T. Intrator, University of Wisconsin, Madison.

8IA 3 Channeling alpha-Particle Power in Tokamaks.
N.J. Fisch, Princeton University.

SESSION 8IB: BASIC MHD

8IB 1 Fast Flow Phenomena in a Toroidal Plasma.
D.J. Den Hartog, University of Wisconsin, Madison.

8IB 2 Effect of Toroidal Plasma Flow and Flow Shear on Global MHD Modes.
M.S. Chu, General Atomics.

8IB 3 Hall Magnetohydrodynamics: Theory and Simulation.
J.D. Huba, Naval Research Laboratory.

SESSION 8IC: EDUCATION AND PUBLIC OUTREACH

8IC 1 Fusion Energy -- Meeting the Challenge (Education Program).
D.L. Correll, Lawrence Livermore National Laboratory.

8IC 2 The Interaction of Researchers with Teachers: What Scientists Can Offer Elementary and Secondary Schools.
R. Holt, Princeton University.

SESSION 8E: ORAL SESSION: ICF DIAGNOSTICS AND LASER TECHNOLOGY

8E 1 Analysis of Spectroscopic Diagnostics Used in Sperical Implosions at Nova.
Y.T. Lee, C.J. Kane, J.K. Nash, G.B. Zimmerman, Lawrence Livermore National Laboratory.

8E 2 Preliminary Spectroscopic Analysis of Core Conditions for High- Growth Factor (HEP4) Capsule Implosions.
G.D. Pollak, Los Alamos National Laboratory.

8E 3 Diagnosing Target Plasma Conditions in Light Ion Beam Experiments Using Intensity Ratios of $K_{\beta}$ Emission Lines.
J.J. MacFarlane and P. Wang, Fusion Technology Institute, University of Wisconsin.

8E 4 High resolution imaging of laser-produced plasmas using x-ray lasers.
R. Cauble, L.B. Da Silva, T.W. Barbee,Jr., P. Celliers, S. Mrowka, J.C. Moreno, A. Wan, and F. Weber, Lawrence Livermore National Laboratory, University of California, Livermore, CA 94550.

8E 5 X-ray laser interferometry for probing high density plasmas.
L.B. Da Silva, T.W. Barbee,Jr., R. Cauble, P. Celliers, H.R. Lee, D.L. Matthews, S. Mrowka, J.C. Moreno, D. Ress, J.E. Trebes, A. Wan, and F. Weber, Lawrence Livermore National Laboratory, University of California, L-447 PO Box 808, Livermore, CA 94550.

8E 6 Characterization of laser-plasma electron-density profiles with a soft x-ray moire deflectometer.
J.E. Trebes, D. Ress, L.B. DaSilva, R.A. London, and P.M. Celliers, Lawrence Livermore National Laboratory, Livermore, CA 94551-5508.

8E 7 Magnetic-Suspension Technique in the Course of Laser Fusion Scheme.
Y. Sakagami, H. Yoshida, Y. Hayashi, M. Sekimura, S. Miyagawa, K. Yasufuku, Gifu University, Japan.

8E 8 X-ray emission from a laser-heated Xe gas puff source.
P. Celliers, L.B. DaSilva, S. Mrowka, H. Kiedorowicz 1, A. Bartnik 1, C.B. Dane and D.L. Matthews, Lawrence Livermore National Laboratory, University of California, L-447 PO Box 808, Livermore, CA 94550. 1=Military University of Technology, Institute of Optoelectronics, Laser-Matter Interaction Section, 01-489 Warsaw 49, Poland.

8E 9 Initial Performance results from the Upgraded OMEGA Laser.
T.R. Boehly, R.S. Craxton, P.A. Jaanimagi, J.H. Kelly, T.J. Kessler, R.L. Kremens, S.A. Kumpan, S.A. Letzring, R.L. McCrory, S.F.B. Morse, W. Seka, S. Skupsky, J.M. Soures, M.D. Tracy, and C.P. Verdon, LLE, U. of Rochester.

8E 10 The Nike KrF Laser Facility.
S.P. Obenschain, S.E. Bodner, K. Gerber, K.J. Kearney, R.H. Lehmberg, E.A. McLean, C.J. Pawley, M.S. Pronko, J.D. Sethian, J.A. Stamper, and C.A. Sullivan, Naval Research Laboratory, Plasma Physics Division; A.V. Deniz, J. Hardgrove, and T. Lehecka, Science Applications International Corp.

8E 11 The NIKE Electron Beam-Pumped KrF Laser Amplifiers.
J.D. Sethian, C.J. Pawley, S.P. Obenschain, K.A. Gerber, and V. Serlin, Plasma Physics Division, Naval Research Laboratory; A.V. Deniz and T. Lehecka, Science Applications International Corp.

SESSION 8F: NUMERICAL TOKAMAK-II; GENERAL COMPUTATIONAL ISSUES II

8F 1 Three-Dimensional Calculations Using the Quiet Implicit PIC Method.
R.A. Nebel, D.C. Barnes, W.D. Nystrom, Los Alamos National Laboratory.

8F 2 Inclusion of Kinetic Electron Effects in $\beta f$ Implicit Moment Particle Simulation.
B.I. Cohen, A.M. Dimits, and J. Stimson, Lawrence Livermore National Laboratory, University of California.

8F 3 Parallized C90 Quasi-ballooning $\beta f$ Gyrokinetic Simulation.
J.A. Byers, A.M. Dimits, B.I. Cohen, T.J. Williams, J.L. Milovich, Lawrence Livermore National Laboratory.

8F 4 MH3D Code Extension Project.
W. Park, G-Y Fu, D. Monticello, N. Pomphrey, H.R. Strauss 1, L. Sugiyama 2, Princeton University. 1=Courant Institute of Mathematical Sciences, New York University; 2=Massachusetts Institute of Technology.

8F 5 A Numerical Scheme for Multidimensional Discontinuous MHD Flows and Its Applications.
W. Dai and P.R. Woodward, Univ. of MN.

8F 6 The Performance of Fluid Codes on Parallel COmputers.
V.E. Lynch, B.A. Carreras, and J.-N. Leboeuf, Oak Ridge, Tennessee 37831-8058.

8F 7 Message-Passing Parallel Quasiballooning Gyrokinetic PIC Code.
T.J. Williams and A.M. Dimits, Lawrence Livermore National Laboratory.

8F 8 Parallel Distributed Visualization Techniques For Numerical Tokamak Simulation Comparison and Analysis.
G.D. Kerbel, R.E. Waltz, J.L. Milovich, D.E. Shumaker and G.W. Hammett, NERSC, General Atomics and PPPL.

8F 9 A Modular 3D Adaptive Grid PIC Code for MIMD Parallel Computers.
Steve Roy Karmesin, California Institute of Technology; J. Wang, Jet Propulsion Laboratory; P.C. Liewer, Jet Propulsion Laboratory; J.U. Brackbill, Los Alamos Scientific Laboratory.

8F 10 New Techniques for Optimizing 3D PIC Simulations using Data Parallel Programming.
J. Thielhaber and S.E. Parker, Thinking Machines Corporation, Princeton Plasma Physics Laboratory.

SESSION 8P: POSTER SESSION: PLASMA PROCESSING AND APPLICATIONS Thursday afternoon, 10 November 1994 Hyatt Center at 14:00

8P 1 Effects of RF B-Fields in Inductive Plasma Sources.
G.J. DePeso, R.H. Cohen, T.D. Rognlien, V. Vahedi, and D.W. Hewett, Lawrence Livermore National Laboratory.

8P 2 Self-Consistent 2-D Model of an Inductively Coupled RF Discharge.
J.L. Giuliani,Jr., R. Terry, M. Mulbrandon and J. Davis, Plasma Physics Division, Naval Research Lab.; A.E. Robson, Berkeley Scholars, Inc.

8P 3 Helicon Sources at Low Fields.
D.W. Aossey and F.F. Chen, UCLA.

8P 4 Absence of Fast Electrons in a Helicon Source.
D.D. Blackwell and F.F. Chen, UCLA.

8P 5 Traveling and Standing Helicon Waves.
M.E. Light, I.D. Sudit, D. Arnush, and F.F. Chen, UCLA.

8P 6 Evidence of Downstream Ion Metastables in an Argon Helicon Plasma.
I.D. Sudit and F.F. Chen, UCLA.

8P 7 Helicon Waves in a Nonuniform Magnetic Field.
D. Arnush and A. Peskoff, UCLA, Los Angeles, CA 90024.

8P 8 Quasineutral Particle Simulations of ECR plasma Processing Devices.
G. Joyce, M. Lampe, W. Manheimer, and S. Slinker, Naval Research Laboratory.

8P 9 Characterization of an ECR Reactor
S.R. Douglass 1, B.V. Weber, Plasma Physics Division; C.R. Eddy, Jr., Surface Modification Branch, Naval Research Lab., Wash., DC 20375. 1=National Research Council Research Associate.

8P 10 Particlate Charging in RF Discharge Sheaths.
D. Winske and Michael E. Jones, Los Alamos Natl. Lab.

8P 11 Particle-in-Cell Simulation of Glow Discharges.
F. Iinoya, G. Lapenta, and J.U. Brackbill, Los Alamos National Laboratory, Los Alamos, NM 87545.

8P 12 Orbit Consistent Plasma Processing Simulations
J.W. Cobb, J.N. Leboeuf, L.A. Berry, E.F. Jaeger, ORNL.

8P 13 Models for Etch Rates Proportional to Ion Energy Flux.
B. Abraham- Shrauner and C.D. Wang, Washington University.

8P 14 Selectivity of etching $Si/SiO_{2}$ in an ECR Etcher with Flourine based Chemistries.
K. Kirmse, A. Wendt, S. Disch, R. Breun, N. Hershkowitz, J. Meyer, J. Wu, C. Woods, Eng. Res. Ctr for Plasma Aided Mfg., University of Wisconsin-Madison.

8P 15 Laser-Ablation-Assisted Discharge Source of Metallic Ions.
J.S. Lash, R.M. Gilgenbach and C.H. Ching, Intense Energy Beam Interaction Laboratory, Nuclear Engineering Department, The University of Michigan, Ann Arbor, Michigan 48109-2104.

8P 16 Dynamics of laser-ablated plasmas.
Kuan-Ren Chen, Jean-Noel Leboeuf, David B. Geohegan, Richard F. Wood, June M. Donato, Chun-Li Liu, and Alex A. Puretzky, ORNL.

8P 17 Mass Spectroscopic Diagnostics for Thermal Plasma CVD of Diamond Films.
H.J. Yoon, P.G. Greuel, D.W. Ernie, and J.T. Roberts, U. of Minnesota.

8P 18 Theoretical and Experimental Studies of Transient Sheaths.
M. Laroussi, S. Kamath, and J.R. Roth, UTK Plasma Science Laboratory, Department of Electrical and Computer Engineering, University of Tennessee, Knoxville, TN 37996-2100.

8P 19 PIC Simulation of Plasma Source Ion Implantation.
R.J. Faehl, B.P. Wood, B. DeVolder, Los Alamos National Laboratory.

8P 20 Studies of Plasma Source Ion Implantation (PSII) Sheath Expansion for Circular Planar Targets.
A. Onuoha, D. Dallmann, J.H. Booske, R. Breun, L. Zhang, P. Sandstrom, W.N.G. Hitchon, and E. Keiter, Engineering Research Center for Plasma-Aided Manufacturing, Univ. of Wisconsin-Madison.

8P 21 Analysis of X Rays Produced During Plasma-Source Ion Implantation.
M. Piper, J.L. Shohet, J.H. Booske, K.H. Chew, J. Jacobs, L. Zhang, Engineering Research Center for Plasma-Aided Manufacturing, U. of Wisconsin-Madison.

8P 22 Hard-Core Surface-Discharge Flashlamp for Blue Laser Pumping.
Jae T. Seo, Kwang S. Han, and Ja H. Lee 1, Dept. of Physics, Hampton University, Hampton, VA 23668. 1=Adjunct Profession, Sr. Scientist, NASA Langley Research Center.

8P 23 Applications of the One Atmosphere Glow Discharge Plasma to Illumination and Aerodynamic Boundary Layer Control.
C. Liu and J.R. Roth, UTK Plasma Science Laboratory, Department of Electrical and Computer Engineering, University of Tennessee, Knoxville, TN 37996- 2100.

8P 24 A High Pressure Plasma Centrifuge for Material Separation.
G. Rosenthal, R.F. Wuerker, A.Y. Wong, UCLA; E.R. Siciliano, Westinghouse Hanford Company.

8P 25 Plasma Centrifuge as a Compact, Low Cost, Stable Isotope Separator.
Niansheng Qi and Mahadevan Krishnan, SRL, 1150 Ballena Blvd., Alameda, CA 94501.

8P 26 Numerical Modeling of an Electron Beam in Air Applied to Electrostatic Painting.
H. Okuda and A.J. Kelly 1, Princeton University. 1=Charged Injection Corporation.

8P 27 Near-Anode Phenomena in an Argon Arc Discharge.
J. Foster and A. Gallimore, U. of Michigan.

SESSION 8Q: POSTER SESSION: LASER PLASMA INTERACTIONS-II

8Q 1 Diagrammatic Approach to Laser-Plasma Interaction.
G. Shvets and J.S. Wurtele, Dept. of Physics, MIT.

8Q 2 Control of Instabilities in Channel Guided Laser Propagation.
J.S. Wurtele and G. Shvets, Massachusetts Institute of Technology.

8Q 3 3D Numerical Simulation of Ultra-intense Laser Pulse in Plasma Channel for Electron Acceleration.
X.L. Chen and R.N. Sudan, Cornell University.

8Q 4 Kinetic Effects in the Wake of a Short Intense laser Pulse.
Patrick Mora, Ecole Polytechnique, France; and Thomas M. Antonsen Jr., University of Maryland, USA.

8Q 5 Investigation of Methods to Enhance Pulse Modulation with Forward Raman Scattering.
D.L. Fisher and T. Tajima, Institute for Fusion Studies, The Univeristy of Texas at Austin.

8Q 6 Stimulated Brillouin and Raman backscatter of short-pulse lasers.
D.E. Hinkel, E.A. Williams, and R.L. Berger, Lawrence Livermore National Laboratory; and W.B. Mori, UCLA.

8Q 7 Pondermotive Effects on Magnetic Fields and Electron Transport under Fast Ignitor Conditions.
R.A. akopp and R.J. Mason, Los Alamos; and M. Glinsky and M. Tabak, Livermore.

8Q 8 Effect of Self-Generated Magnetic Fields on Suprathermal Electron transport.
M.E. Glinsky and M. Tabak, Lawrence Livermore National Laboratory; and R.J. Mason, Los Alamos National Laboratory.

8Q 9 Magnetic field generation by intense ultrashort laser pulses in underdense plasmas.
V.Yu. Bychenkov and V.T. Tikhonchuk, P.N. Lebedev Physics Institute, Russian Academy of Sciences, Moscow, Russia.

8Q 10 Laser-Induced Circulating Currents.
William L. Kruer, Lawrence Livermore National Laboratory.

8Q 11 Two-Dimensional Stimulated Brillouin Scattering.
R.E. Giacone, C.J. McKinstrie, T. Kolber, and R. Betti, LLE, U. of Rochester.

8Q 12 The role of the hot spot length compared to the plasma length in determining the growth of stimulated Brillouin scattering.
T.B. Kaiser, R.L. Berger, D.E. Hinkel, B.F. Lasinski, B.B. Afeyan, B.I. Cohen, A.B. Langdon, and E.A. Williams, Lawrence Livermore National Laboratory.

8Q 13 Brillouin scattering in three dimensions: Tools for Display and Analysis.
C.H. Still, B.B. Afeyan, R.L. Berger, B.I. Cohen, T. Kaiser, A.B. Langdon, B.F. Lasinski, and E.A. Williams, Lawrence Livermore National Laboratory.

8Q 14 The Stimulated Brillouin Instability in Inhomogeneous, Flowing Plasmas From Back to Sidescattering.
Bedros B. Afeyan and Edward A. Williams, Lawrence Livermore National Laboratory.

8Q 15 Nonlinear Theory and Simulations of Stimulated Brillouin Backscatter in Multi-Ion Plasmas.
K. Estabrook, S.C. Wilks, W. L. Kruer, J. Denavit, D.E. Hinkel, D. Kalantar, A.B. Langdon, B. MacGowan, D. Montgomery, J. Moody, and E.A. Williams, Lawrence Livermore National Laboratory.

8Q 16 Convective Threshold of Stimulated Brillouin Backscattering in a Two-Ion-Component Plasma.
B. Bezzerides, J.M. Wallace, and H.X. Vu, Los Alamos National Laboratory.

8Q 17 An Analytical and Numerical Investigation of Ion Acoustic Waves in an Two-Ion-Component Plasma.
H.X. Vu, J.M. Wallace, and B. Bezzerides, Los Alamos National Laboratory.

8Q 18 Anomalous Transport in Plasmas with Two Ion Species.
V. Stefan, and S.A. Uryupin 1, Tesla Laboratories, Inc., La Jolla, CA. 1=P.N. Lebedev Physics Institute, Russian Academy of Sciences, Moscow, Russia.

8Q 19 The effects of Multiple Scattering on Charged-Particle Linear- Energy-Transfer in Dense Plasmas.
C.K. Li and R.D. Petrasso. MIT Plamsa Fusion Center.

8Q 20 Inverse Bremsstrahlung Absorption and Electron Heat Transport.
J.M. Liu 1, J.S. De Groot 1, J.P. Matte 2, T.W. Johnson 2, W.L. Kruer 2, and R.P. Drake 4. 1=UC Davis; 2=INRS-Energie, varennes, Quebec, Canada; 3=LLNL; 4=PPRI, LLNL and UC Davis.

8Q 21 Applications of the Ion Acoustic Decay Instabilities to Critical Surface Diagnostic in a Large Scale, Hot Plasma.
K. Mizuno 1, R. Bahr 2, S. Craxton 2, J. DeGroot, R.P. Drake 1, W. Seka 2, UC Davis. 1=PPRI; 2=LLE.

8Q 22 Production and characterization of a long-scale-length plasma, with a critical surface and parallel flow, for laser-plasma experiments.
R.P. Drake, B.S. Bauer, Kent Estabrook, and J.F. Camacho, Plasma Physics Research Institute, Lawrence Livermore National Laboratory, Livermore, CA 94550; R.G. Watt, M.d. Wilke, J. Cobble, R. Hockaday, G.E. Busch, and S.E. Caldwell, Los Alamos National Laboratory, S.A. Baker, EG&G-LAO.

8Q 23 Investigation of the effect of F number on stimulated backscatter using Trident.
R.G. Watt, J. Fernandez, D. DuBois, H.A. Rose, Los Alamos National Laboratory; P. Drake, B. Bauer, Lawrence Livermore National Laboratory.

8Q 24 Fluid and Kinetic Modeling of Trident Colliding Plasma Experiments.
V.G. Rogatchev, A. Bel'kov, P.D. Gasparyan, G.V. Dolgoleva, N.V. Ivanov, Uu.K. Kochubej, G.F. Nasyrov, V.A. Pavlovskii, V.V. Smirnov, Yu.A. Romanov, VNIIEF, Russia; Michael E. Jones, S.R. Goldman, V.A. Thomas, D. Winske, Los Alamos Natl Lab.

8Q 25 Kinetic MC-PIC Simulations of Axially Stagnating Plasma.
P.W. Rambo, University of California, Lawrence Livermore National Laboratory.

8Q 26 Full 2D-Hybrid Simulations of Laser-Produced Plasma Expansion in a Magnetized Plasma.
F. Simonet (CEA/Centre d'Etudes de Limeil- Valenton); B. Lembege (CTEP/CNET Issy les Moulineaux); F. Pierronne (CISI under CEA/CESTA contract, Bourdeaux).

SESSION 8R: POSTER SESSION: NON-NEUTRAL PLASMAS AND TRAPS

8R 1 Resolving The Wave - Particle Paradox of The Electron.
IGOR Alexeff, ECE, The University of Tennessee, Knoxville, 37996-2100.

8R 2 Formation of Electron-Positron Plasmas in the Laboratory.
H. Boehmer, M. Adams, and N. Rynn, Department of Physics, University of California, Irvine.

8R 3 Advances in positron plasma experiments.
R.G. Greaves, M.D. Tinkle, and C.M. Surko, University of California, San Diego.

8R 4 Modes of a pure ion plasma at the Brillouin limit.
M.D. Tinkle, R. G. Greaves, and C.M. Surko, University of California, San Diego.

8R 5 Production of a Positron-Electron Plasma.
J.H. Hartley, T.E. Cowan, B.R. Beck, LLNL; J. Fajans, R. Gopalan, U.C. Berkeley.

8R 6 Electron Vortex Dynamics in an Irrotational Shear Flow: Comparison with the 2-D Fluid Theory of Moore and Saffman.
D.L. Eggleston, Occidental College.

8R 7 Observations of Vortex Crystals in 2D Turbulence.
K.S. Fine, C.F. Driscoll and A.C. Cass, Univ. of Calif., San Diego.

8R 8 Off-Axis and "Haloed" Equilibria from a Minimum Enstrophy Analysis of the Relaxation of 2-D Turbulence.
G.M. Sandler and D.H.E. Dubin, Univ. of Calif., San Diego.

8R 9 Transport from Rotational Pumping of a Magnetized Pure Electron Plasma.
B. Cluggish and C.F. Driscoll, Univ. of Calif., San Diego.

8R 10 Transport Due to Rotational Pumping.
S.M. Crooks and T.M. O'Neil, Univ. of Calif., San Diego.

8R 11 Spin-up of Nonneutral Plasmas by Rotating Walls.
X.-P. Huang, F. Anderegg, R.E. Pollock 1, T.M. O'Neil, G.D. Severn 2, and C.F. Driscoll, Univ. of Calif., San Diego. 1=Indiana University; 2=Univ. of San Diego.

8R 12 Confinement Time Scalings of Non-neutral Plasmas.
A.C. Cass, B. Cluggish, F. Anderegg, K.S. Fine, C.D. Driscoll, and E. Sarid 1, Univ. of Calif., San Diego. 1=KAMAG, Beer-Sheva, Israel.

8R 13 In Situ LIF Measurements of a Pure Ion Plasma.
F. Anderegg, X.-P. Huang, G.D. Severn 1, and C.F. Driscoll, Univ. of Calif., San Diego. 1=Univ. of San Diego.

8R 14 Normal Modes of a Strongly Correlated Plasma in a Harmonic Trap.
J.P. Schiffer, Argonne National Lab. and Univ of Chicago and D.H.E. Dubink, Univ. of Calif., San Diego.

8R 15 Recent Results With Large Numbers of Laser-Cooled Ions in a Penning Trap.
Joseph N. Tan, J.J. Bollinger, and D.J. Wineland, NIST, Boulder, CO 80303.

8R 16 Trapping of Highly Ionized Ions in a Cyrogenic Penning Trap.
B.R. Beck 1, D. Schneider 1, D.A. Church 2, G. Weinberg 2, J. Steiger 1, D. Knapp 1. 1=Lawrence Livermore National Laboratory; 2=Texas A&M University.

8R 17 Stability Studies for Systems with Convergent Flow.
Nicholas A. Krall, Krall Associates.

8R 18 New Electron Plasma Trap.
M.D. Behn, J. Notte, Bates College, Lewiston, ME.

8R 19 Negative Energy and Dispersion of the Diocotron Resonances.
Sateesh Pillai and Roy W. Gould, California Isntitute of Technology.

8R 20 Numerical Collisionless Damping of the Diocotron resonance.
David A. Bachman and Roy W. Gould, California Isntitute of Technology.

8R 21 PFX - The Los Alamos Penning Trap Fusion Experiment.
D.W. Scudder, T.B. Mitchell, D.C. Barnes, M.H. Holzscheiter, Los Alamos National Laboratory.

8R 22 PFX - Design and Diagnostics.
T.B. Mitchell, M.H. Holzscheiter, D.W. Scudder, D.C. Barnes, Los Alamos National Laboratory.

8R 23 Scaling of Spherical, Nonneutral Fusion Systems to Reactor Size.
D.C. Barnes, R.A. Nebel, T.N. Tiouririne.

8R 24 Dynamics of Coupled Ions in Traps.
J.R. Sobehart, Center for Nonlinear Sutdies--Los Alamos National Laboratory; R. Farengo, Division Fusion Nuclear -- comision Nacional de Energia Atomica.

8R 25 Electrostatic Instabilities in Penning Traps.
T.N. Tiouririne, J.M. Finn, D.C. Barnes, Los Alamos National Laboratory.

8R 26 Streaming Instabilities in Nonneutral Plasmas with Turning Points.
Leaf Turner and John M. Finn, Los Alamos National Laboratory.

8R 27 EIXL V2.3; A Steady-State Simulation of IEF IXL/EXL Systems.
Lorin W. Jameson and Robert W. Bussard, Energy/Matter Conversion Corporation (EMC2).

8R 28 Numerical Simulation of Inertial Electrostatic Fusion.
K.H. Simmons and J.F. Santarius, Fusin Technology Institute, University of Wisconsin-Madison.

8R 29 Modelling Inertial-Electrostatic-Confinement Fusion Devices.
J.F. Santarius, K.H. Simmons, and G.A. Emmert, Fusin Technology Institute, University of Wisconsin-Madison.

8R 30 The UW Spherical Ion Focus Experiment.
L.P. Wainwright, R.D. Durst, R.J. Fonck, and T.A. Thorson, University of Wisconsin-Madison.

8R 31 Initial Results from the UW Spherical Ion Focus Experiment.
T.A. Thorson, R.A. Buckles, R.D. Durst, R.J. Fonck, and L.P. Wainwright, University of Wisconsin-Madison.

8R 32 Numerical Studies of Nonneutral Plasmas.
A.Y. Aydemir, Institute for Fusion Studies, The Univeristy of Texas at Austin.

8R 33 Simulations of Low-Frequency, Temperature-Dependent, Electrostatic Modes in Non-neutral Plasmas.
Grant W. Mason, Jonathan A. Bennett and Ross L. Spencer, Department of Physics and Astronomy, Brigham Young University, Provo, Utah 84602.

8R 34 Investigation of the Decay of $^{7}Be$ Using a Non-Neutral Ion Plasma.
B.G. Peterson, G.W. Hart, S.E. Jones, Brigham Young University, Provo, UT.

8R 35 Mode Frequencies of Warm Spheroidal Non-neutral Plasmas.
Ross L. Spencer, K.C. Hansen, and Grant W. Mason, Department of Physics and Astronomy, Brigham Young University, Provo, Utah 84602.

8R 36 Inertial-Electrostatic Confinement Studies.
C.K. Rowdyshrub, New Paris Polytechnique Institute, PA; R.A. Nebel, T.N. Tiouririne, D.C. Barnes, W.D. Nystrom, Los Alamos National Laboratory; G.H. Miley, I. Tzonev, B. Bromley, University of Ill.

8R 37 Transport in Pure Electron Plasmas and its Implications for Pressure Measurement.
D.A. Moore, R.C. Davidson, S.M. Kaye, and S.F. Paul, Princeton Plasma Physics Laboratory, Princeton, NJ 08543.

8R 38 Stability of highly deformed asymmetric noneutral plasmas.
J. Fajans, U.C. Berkeley.

8R 39 Attainment of axial equiulibria and Debye shielding in nonneutral plasmas.
C. Hansen and J. Fajans, U.C. Berkeley.

8R 40 Plasma Escape Due to Oscillating End Potentials in Nonneutral Plasmas.
G.W. Hart and K.C. Handen, Brigham Young University, Provo, Utah.

SESSION 8S: MICROWAVE GENERATION

8S 1 Recent Test results on a High-Power Gyrotron with a Gaussian Output Mode.
K. Felch, T.S. Chu, W. DeHope, H. Huey, H. Jory, J. Neilson, R. Schumacher, Varian Associates, Inc.

8S 2 Tapering of Gyrotron-Backward-Wave-Oscillators Driven by A Microsecond, Intense E-Beam.
M.T. Walter, R.M. Gilgenbach, J.M. Hochman, C.H. Chang, J. Luginsland, and T.A. Spencer 1, Intense Energy Beam Interaction Laboratory, Nuclear Eng. Dept., Univ. of Michigan, Ann Arbor, MI. 1=Air Force Phillips Lab, Kirtland AFB, NM.

8S 3 Stable High-Performance $TE_{01}$ Gyro-TWT.
D.B. McDermott, K.C. Leou, C.K. Chong, and N.C. Luhmann,Jr., Department of Applied Science, University of California, Davis and Lawrence Livermore National Laboratory.

8S 4 High Power, $n^{th}$-Harmonic $TE_{n1}$ Gyro-TWT's: 200 kW Second- Harmonic Results and 1 MW Third-Harmonic Design.
Q.S. Wang, D.B. McDermott, A.J. Balkcum, and N.C. Luhmann,Jr., Department of Applied Science, University of California, Davis and Lawrence Livermore National Laboratory.

8S 5 Sixth-Harmonic Gyrofrequency-Multiplier Results.
A.J. Balkcum, D.B. McDermott, and N.C. Luhmann,Jr., Department of Applied Science, University of California, Davis and Lawrence Livermore National Laboratory.

8S 6 Slotted Third-Harmonic Gyro-TWT Results.
C.K. Chong, D.B. McDermott, A.J. Balkcum, N.C. Luhmann,Jr., Department of Applied Science, University of California, Davis and Lawrence Livermore National Laboratory; A.T. Lin, Dept. of Physics, UCLA, and W.J. DeHope, Varian Associates.

8S 7 Disk-Loaded Wideband Gyro-TWT.
K.C. Leou, D.B. McDermott, A.J. Balkcum, N.C. Luhmann,Jr., Department of Applied Science, University of California, Davis and Lawrence Livermore National Laboratory.

8S 8 Multi-mode Analysis of Gyroklystron Amplifiers.
P.E. Latham, University of Maryland at College Park.

8S 9 Design of Fundamental Mode and Second-Harmonic High-Power Coaxial Gyroklystrons for Collider Applications.
W. Lawson, J. P. Calame, J. Cheng, M. Castle, P.E. Latham, and B. Hogan, University of Maryland at College Park.

8S 10 Two-Stage Tapered Gyro-Traveling Wave Tube Amplifier Experiment.
G.S. Park 1, J.J. Choi 2, S.Y. Park 3, C.M. Armstrong 4, A.K. Ganguly 1, K.T. Nguyen 5, R.H. Keyser 6, and R.K. Parker, Naval Research Laboratory. 1=Omega-P, Inc., New Haven CT 06520; 2=SAIC, McLean, VA 22102; 3=Dept. of Physics, Pohang Inst. Sci, and Tech, Pohang, Korea and Omega-P, Inc.; 4=Northrop Corporation, Rolling Meadow, IL 60008; 5=KN Research, Silver Spring, MD 20906; 6=B-K Systems, Inc. Rockville, MD 20850.

8S 11 High Power, Broadband Millimeter Wave Gyro-Amplifier research.
J.J. Choi 1, C.M. Armstrong 2, A.K. Ganguly 3, F. Calise 4, and R.K. Parker, Naval Research Laboratory, Washington, DC. 1=SAIC, McLean, VA 22102; 2=Northrop Corporation, Rolling Meadows, IL 60008; 3=Omega-P, Inc. New Haven, CT 06520; 4=B-L Systems, Inc., Rockville, MD 20850.

8S 12 Generation of Peniotron Mode Radiation in a 16 Slotted Cusptron Oscillator.
E. Koretzky, J. Kim and S.P. Kuo, Weber Research Institute, Polytechnic University, Farmingdale, NY 11735.

8S 13 Helix Peniotron with the Transverse Electric Mode.
Saeyoung Ahn, Washington, DC 20375-5347, Naval Research Laboratory.

8S 14 High Power Millimeter Wave Transit-Time Amplifier.
M. Joseph Arman, Phillips Laboratory, Electromagnetic Sources Division, 3550 Aberdeen Ave. SE, Kirtland AFB, NM 87117-5776.

8S 15 Rf generation from an Annular Electron Beam Modulated by a Klyston- like Amplifier.
K.J. Hendricks 1, P.D. Coleman 2, M.D. Sena 3, R. Gallegos 2, Brian Haynes 4, Mike Fazio 4, L.A. Bowers 1, C.E. Davis 1, R.T. Peredo 1, T.A. Spencer 1, D.L. Ralph 5, M.J. Arman 1, R. Lemke 2, M.C. Clark 2, K.E. Hackett 1. 1=Electromagnetic Sources Division, Phillips Laboratory, Kirtland AFB, NM; 2=Sandia National Laboratory, Albuquerque, NM; 3=Maxwell Laboratories, Albuquerque, NM; 5=Los Alamos National Laboratory, Los Alamos, NM.

8S 16 Gyrotron-Backward-Wave Oscillator Experiments.
T.A. Spencer, C.E. Davis, M.J. Arman, K.J. Hendricks, K.E. Hackett, R.T. Peredo, R.M. Gilgenbach 1, R. Sedillo 2, D.L. Ralph 2, M.Scott 2, The Air Force Phillips Laboratory, PL/WSR, Electromagnetics Sources Division, Bldg. 66091, 3550 Aberdeen Ave Se, Kirtland AFB, NM 97117-5776. 1=Nuclear Engin. Dept. Univ. of Michigan, A^2, MI 48109-2104; 2=Maxwell Laboratory, Inc. Albuquerque, NM.

8S 17 Initial Tests of an X-Band Magnicon Amplifier.
S.H. Gold, C.A. Sullivan, B. Hafizi 1, A.W. Fliflet, and W.M. Manheimer, Naval Research Laboratory. 1=Icarus Research, Bethesda, MD 20814.

8S 18 Optimization Studies of Magnicon Efficiency.
B. Hafizi, Icarus Research; and S.H. Gold, Plasma Physics Division, Naval Research Laboratory.

8S 19 The Nonlinear Simulation of Helix Traveling Wave Tubes.
E.G. Zaidman, H.P. Freund 1, M.A. Kodis, and N.R. Vanderplaats, Naval Research Laboratory. 1=SAIC, McLean, VA 22102.

8S 20 Initial Experimental Investigation of Low-Voltage, Grating TWT Amplifiers.
J. Joe, M.A. Basten, J.E. Scharer, J.H. Booske, University of Wisconsin-Madison.

8S 21 Smith-Purcell Experiments with a Scanning Electron Microscope.
M. Goldstein and J.E. Walsh, Dartmouth College.

8S 22 Forward Peaking of Relativistic Electron-Beam-Generated Smith- Purcell Radiation.
K.J. Woods, Dartmouth College; R.E. Stoner, MIT; R. Fernow, H. Kirk, and J.E. Walsh, Brookhaven National Laboratory.

8S 23 Smith-Purcell Radiation in the Relativistic Limit.
J.E. Walsh, S.G. Yeager, and K.J. Woods, Dartmouth College.

8S 24 Frequency Mismatch in Relativistic Klystron Amplifier.
H.C. Chen, Naval Surface Warfare Center, White Oak, Silver Spring, MD.

8S 25 $PASOTRON^TM$ Amplifier Experiments.
J.M. Butler, D.M. Goebel, J. Santoru, E.S. Garland, Hughes Research Labs; and R.L. Eisenhart, Hughs Missile Systems Co.

8S 26 $Helix-PASOTRON^TM$ Investigations.
D.M. Goebel, J.M. Butler, R.R. Robson, Hughes Research Labs; and R.L. Eisenhart, Hughs Missile Systems Co.

8S 27 Multi-Stage $PASOTRON^TM$ Experiments.
E.S. Garland, J.M. Butler, J. Santoru, D.M. Goebel, Hughes Research Labs; and R.L. Eisenhart, Hughs Missile Systems Co.

8S 28 Twystrode Experiments with Helical Circuits.
M.A. Kodis, N.R. Vanderplaats, E.G. Zaidman, H.P. Freund 1, Naval Research Laboratory; and D.N. Smithe, G. Goplen, Mission Research Corporation. 1=SAIC, McLean, VA 22102.

8S 29 Particle-in-Cell Simulations of High Efficiency Twystrodes.
David Smithe and Bruce Goplen, Mission Research Corporation.

8S 30 Experimental Results of a "Scanner" Microwave Amplifier.
J.E. Velazco, P.H. Cerperley, W.M. Black, K. Thomason, George Mason University; and T.F. Godlove, F.M. Mako, FM Technologies, Inc. Fairfax, VA.

8S 31 Megawatt-Level Millimeter-Wave Source for Plasma Heating and Control.
A.K. Ganguly, Omega-P, Inc.; Changbiao Wang, Yale Univ.; and J.L. Hirshfield, Omega-P, Inc. and Yale Univ.

8S 32 A Fifth Harmonic Converter for Production of Multi-Megawatt, 14.28 GHz Microwaves.
M.A. LaPointe, J.H. Hirshfield and R.B. Yoder, Omega-P, Inc. and Yale University.

8S 33 Stimulated Microwave Emission from E x B Drifting Beams.
D. Chernin and S. Riyopoulos, SAIC.

8S 34 Effects of Bipolar Flow on Microwave Emission in a Vircator.
D. Young and O. Ishihara, Texas Tech University and M. Yatsuzuka, Himiji Institute of Technology, Japan.

SESSION 8T: POSTER SESSION: PUBLIC OUTREACH AND EDUCATION

8T 1 Science and Technology - Meeting the Needs of the Future.
Eileen S. Vergino, Lawrence Livermore National Laboratory, L793, PO Box 808, Livermore, CA 94550.

8T 2 The Fusion Education Group at the MIT Plasma Fusion Center.
S.A. Fairfax, and the Fusion Education Group at the MIT Plasma Fusion Center.

8T 3 Education Outreach: General Atomics Fusion Group.
C.A. Danielson, D. P. Schissel, A.M. Bilinski, R.E. Brown, C.M. Greenfield, K.M. Keith, D.N. Kessler, R.L. Lee, J.A. Leuer, J.M. Lohr, L. Pina 1, S.B. Rodecker 2, P.S. Showalter, M.P. Thomas, S.G. Visser, P. Winter, and the Fusion Group, General Atomics. 1=Roosevelt Junior High School, San Diego, CA; 2=Chula Vista High School, Chula Vista, CA.

8T 4 Vocal Instabilities of Pre-Adolescent Children Exposed to High Electric Field Gradients.
P. Thomas, MIT Plasma Fusion Center.

8T 5 Plasma Physics and Fusion Energy Educatinal Materials from CPEP.
Ted Zaleskiewicz 1, D. Correll 2, S. Fairfax 3, R.D. Holt 4, R. Reiland 5, and D. Schissel 6, for the Fusion Committee of CPEP. 1=University of Pittsburgh, Greenburg, PA; 2=Lawrence Livermore National Laboratory, Livermore, CA; 3=Plasma Fusion Center, Massachusetts Institute of Technology, Cambridge, MA; 4=Princeton Plasma Physics Laboratory, Princeton, NJ; 5=Shady Side Academy, Pittsburgh, PA; 6=General Atomics, San Diego, CA.

8T 6 The Sci. Physics. Fusion Conventional Fusion FAQ.
R.F. Heeter, Princeton University.

8T 7 National Undergraduate Fellowships in Plasma Physics and Fusion Engineering.
R.D. Holt, N. Fisch, D. Carroll, Princeton Plasma Physics Laboratory, for the Committee of the N.U.F. program.

SESSION 8IF: THE NEXT LARGE DEVICES IN THE MAGNETIC FUSION PROGRAM

8I 1 ITER: Mission and Machine.
R. Aymar, ITER, France.

8I 2 The Tokamak Physics Experiment.
R. Davidson, Princeton Plasma Physics Laboratory.

8I 3 The Next Large Helical Devices.
A. Iiyoshi, NIFS, Japan.