Your search keyword '"E. J. Synakowski"' showing total 12 results

1. Dominance of convective heat transport in the core of TFTR (Tokamak Fusion Test Reactor) supershot plasmas

Author

E. J. Synakowski, P. C. Efthimion, James D. Callen, J.F. Schivell, Hyeon K. Park, C.E. Bush, D.K. Mansfield, G. Taylor, and Michael W Kissick

Subjects

Fluid Flow and Transfer Processes, Physics, Convection, Convective heat transfer, Computational Mechanics, General Physics and Astronomy, chemistry.chemical_element, Plasma, Condensed Matter Physics, Nuclear physics, Heat flux, chemistry, Physics::Plasma Physics, Mechanics of Materials, Heat transfer, Electron temperature, Tokamak Fusion Test Reactor, Helium

Abstract

Using perturbations in electron density and temperature induced by small helium gas puffs in TFTR (Tokamak Fusion Test Reactor) [Plasma Phys. Controlled Nucl. Fusion Res. 1, 51 (1986)], the dominance of convective heat transport in the core (r/a

Published

1993

2. Helium, iron, and electron particle transport and energy transport studies on the Tokamak Fusion Test Reactor

Author

D. R. Mikkelsen, R. A. Hulse, G. Taylor, M. H. Redi, G. Rewoldt, William Tang, S. D. Scott, M. C. Zarnstorff, D. C. McCune, P. C. Efthimion, J. Timberlake, A. T. Ramsey, Michael W Kissick, D. K. Mansfield, B. Grek, David W. Johnson, Brentley Stratton, E. J. Synakowski, Hyeon K. Park, and K. W. Hill

Subjects

Fluid Flow and Transfer Processes, Physics, Tokamak, Computational Mechanics, General Physics and Astronomy, chemistry.chemical_element, Plasma, Electron, Condensed Matter Physics, Thermal diffusivity, law.invention, Heat flux, chemistry, Physics::Plasma Physics, Mechanics of Materials, law, Atomic physics, Diffusion (business), Tokamak Fusion Test Reactor, Helium

Abstract

Results from helium, iron, and electron transport studies on the Tokamak Fusion Test Reactor (TFTR) [Plasma Phys. Controlled Nucl. Fusion Res. 26, 11 (1984)] in L‐mode and supershot deuterium plasmas with the same toroidal field, plasma current, and neutral beam heating power are presented. They are compared to results from thermal transport analysis based on power balance. Particle diffusivities and thermal conductivities are radially hollow and larger than neoclassical values, except possibly near the magnetic axis. The ion channel dominates over the electron channel in both particle and thermal diffusion. A peaked helium profile, supported by inward convection that is stronger than predicted by neoclassical theory, is measured in the supershot. The helium profile shape is consistent with predictions from quasilinear electrostatic drift‐wave theory. While the perturbative particle diffusion coefficients of all three species are similar in the supershot, differences are found in the L mode. Quasilinear theory calculations of the ratios of impurity diffusivities are in good accord with measurements. Theory estimates indicate that the ion heat flux should be larger than the electron heat flux, consistent with power balance analysis. However, theoretical values of the ratio of the ion to electron heat flux can be more than a factor of 3 larger than experimental values. A correlation between helium diffusion and ion thermal transport is observed and has favorable implications for sustained ignition of a tokamak fusion reactor.

Published

1993

3. Ion cyclotron range of frequency heating on the Tokamak Fusion Test Reactor*

Author

C.E. Bush, K. L. Wong, N. L. Bretz, M. G. Bell, D.K. Mansfield, F. C. Jobes, Manfred Bitter, J.F. Schivell, C. K. Phillips, Liu Chen, S.F. Paul, F. Rimini, Raffi Nazikian, G. L. Schmidt, J. C. Hosea, B. Grek, D. L. Jassby, E.D. Fredrickson, R. C. Goldfinger, D. Mueller, A.C. Janos, H. Biglari, J. Machuzak, M. Murakami, D. J. Hoffman, L. R. Grisham, B. C. Stratton, Hyeon K. Park, J. E. Stevens, S. S. Medley, G. Taylor, D. K. Owens, E. J. Synakowski, G. Schilling, J. D. Strachan, Stewart Zweben, R.V. Budny, James R. Wilson, Gregory W. Hammett, E. Mazzucato, Richard Majeski, D. S. Darrow, David A Rasmussen, Darin Ernst, A. L. Qualls, P. C. Efthimion, Guoyong Fu, L. C. Johnson, David W. Johnson, Larry R. Baylor, J. H. Rogers, and Z. Chang

Subjects

Fluid Flow and Transfer Processes, Physics, Cyclotron, Computational Mechanics, Cyclotron resonance, General Physics and Astronomy, Plasma, Condensed Matter Physics, law.invention, Nuclear physics, Heating system, Mechanics of Materials, law, Helium-3, Electron temperature, Tokamak Fusion Test Reactor, Ion cyclotron resonance

Abstract

The complete ion cyclotron range of frequency (ICRF) heating system for the Tokamak Fusion Test Reactor (TFTR) [Fusion Tech. 21, 1324 (1992)], consisting of four antennas and six generators designed to deliver 12.5 MW to the TFTR plasma, has now been installed. Recently a series of experiments has been conducted to explore the effect of ICRF heating on the performance of low recycling, supershot plasmas in minority and nonresonant electron heating regimes. The addition of up to 7.4 MW of ICRF power to full size (R∼2.6 m, a∼0.95 m), helium‐3 minority, deuterium supershots heated with up to 30 MW of deuterium neutral‐beam injection has resulted in a significant increase in core electron temperature (ΔTe=3–4 keV). Simulations of equivalent deuterium–tritium (D–T) supershots predict that such ICRF heating should result in an increase in βα(0)∼30%. Direct electron heating has been observed and has been found to be in agreement with theory. The ICRF heating has also been coupled to neutral‐beam heated plasmas f...

Published

1993

4. High poloidal beta long‐pulse experiments in the Tokamak Fusion Test Reactor*

Author

S. H. Batha, Fred Levinton, A. T. Ramsey, M. G. Bell, Gerald Navratil, Hyeon K. Park, B. Grek, A.C. Janos, E.D. Fredrickson, D.K. Mansfield, D.C. McCune, C.E. Bush, G. Taylor, M. C. Zarnstorff, Jay Kesner, S.A. Sabbagh, K. M. McGuire, Michael E. Mauel, E. J. Synakowski, R.V. Budny, and David W. Johnson

Subjects

Fluid Flow and Transfer Processes, Physics, Resistive touchscreen, Long pulse, Computational Mechanics, General Physics and Astronomy, Plasma, Condensed Matter Physics, Instability, Neutral beam injection, Plasma current, Nuclear physics, Mechanics of Materials, Nuclear fusion, Atomic physics, Tokamak Fusion Test Reactor

Abstract

Experiments have been performed in the Tokamak Fusion Test Reactor [D. M. Meade et al. in Plasma Physics Controlled Nuclear Fusion Research, 1990 (International Atomic Energy Agency, Vienna, 1991), Vol. 1, p. 9] with neutral beam injection of up to 4 sec. duration, which is comparable to the time scale for resistive redistribution of the plasma current profile. These plasmas were created using a rapid decrease of the plasma current which initially created a plasma with enhanced stability and confinement. As the current profile evolved, a significantly reduced beta limit was observed. The high eβp plasmas had up to 90% of the current driven noninductively which significantly broadened the current profile during the long pulse lengths. These experiments demonstrated that high βN plasmas could not be sustained for times longer than the resistive relaxation of the outer current region which at early times after the current ramp‐down carried negative current. At later times in lower βN discharges, beta collaps...

Published

1993

5. Ion cyclotron range of frequencies stabilization of sawteeth on Tokamak Fusion Test Reactor

Author

G. Schilling, J. R. Wilson, J.F. Schivell, Chio-Zong Cheng, Manfred Bitter, R. Boivin, D. K. Owens, H. H. Towner, M. G. Bell, J.L. Terry, J.A. Snipes, E.D. Fredrickson, C. K. Phillips, David Smithe, D. Hoffman, J. E. Stevens, Hyeon K. Park, E. J. Synakowski, Gregory W. Hammett, K. M. McGuire, B. C. Stratton, W. A. Houlberg, C.E. Bush, M. W. Phillips, E.S. Marmar, Roscoe White, M. Hughes, A. T. Ramsey, D.C. McCune, H. Hsuan, Stewart Zweben, R. C. Goldfinger, D.S. Darrow, Yoshio Nagayama, G. Taylor, K. W. Hill, D. L. Jassby, and J. Hosea

Subjects

Fluid Flow and Transfer Processes, Physics, Tokamak, Cyclotron, Computational Mechanics, General Physics and Astronomy, Context (language use), Sawtooth wave, Plasma, Condensed Matter Physics, law.invention, Magnetic field, Physics::Plasma Physics, Mechanics of Materials, law, Magnetohydrodynamics, Atomic physics, Tokamak Fusion Test Reactor

Abstract

Results obtained from experiments utilizing high‐power ion cyclotron range of frequencies (ICRF) heating to stabilize sawtooth oscillations on Tokamak Fusion Test Reactor (TFTR) [Hawryluk et al., Plasma Phys. Controlled Fusion 33, 1509 (1991)] are reviewed. The key observations include existence of a minimum ICRF power required to achieve stabilization, a dependence of the stabilization threshold on the relative size of the ICRF power deposition profile to the q=1 volume, and a peaking of the equilibrium pressure and current profiles during sawtooth‐free phases of the discharges. In addition, preliminary measurements of the poloidal magnetic field profile indicate that q on axis decreases to a value of 0.55±0.15 after a sawtooth‐stabilized period of ∼0.5 sec has transpired. The results are discussed in the context of theory, which suggests that the fast ions produced by the ICRF heating suppress sawteeth by stabilizing the m=1 magnetohydrodynamic (MHD) instabilities believed to be the trigger for the sawtooth oscillations. Though qualitative agreement is found between the observations and the theory, further refinement of the theory coupled with more accurate measurements of experimental profiles will be required in order to complete quantitative comparisons.

Published

1992

6. Investigation of global Alfvén instabilities in the Tokamak Fusion Test Reactor

Author

Hyeon K. Park, E. J. Synakowski, R. Durst, K. L. Wong, M. G. Bell, Steven Sabbagh, S. S. Medley, Samuel Cohen, Gregory W. Hammett, F. C. Jobes, D. R. Roberts, Y. Nagayama, Chio-Zong Cheng, Dale Meade, Raffi Nazikian, R. J. Fonck, N. Bretz, Robert Budny, S. Paul, D. Mueller, E.D. Fredrickson, L. C. Johnson, and D. K. Owens

Subjects

Fluid Flow and Transfer Processes, Physics, Neutron emission, Computational Mechanics, General Physics and Astronomy, Plasma, Condensed Matter Physics, Instability, Magnetic field, Alfvén wave, Physics::Plasma Physics, Mechanics of Materials, Neutron source, Atomic physics, Tokamak Fusion Test Reactor, Beam (structure)

Abstract

Toroidal Alfven eigenmodes (TAE) were excited by the energetic neutral beam ions tangentially injected into plasmas at low magnetic field in the Tokamak Fusion Test Reactor (TFTR) [Proceedings of the 11th International Conference on Plasma Physics and Controlled Fusion Research (IAEA, Vienna, 1987), Vol. 1, p. 51]. The injection velocities were comparable to the Alfven speed. The modes were identified by measurements from Mirnov coils and beam emission spectroscopy (BES). TAE modes appear in bursts whose repetition rate increases with beam power. The neutron emission rate exhibits sawtoothlike behavior and the crashes always coincide with TAE bursts. This indicates ejection of fast ions from the plasma until these modes are stabilized. The dynamics of growth and stabilization were investigated at various plasma currents and magnetic fields. The results indicate that the instability can effectively clamp the number of energetic ions in the plasmas. The observed instability threshold is discussed in light of recent theories. In addition to these TAE modes, intermittent oscillations at three times the fundamental TAE frequency were observed by Mirnov coils, but no corresponding signal was found in BES. It appears that these high‐frequency oscillations do not have a direct effect on the plasma neutron source strength.

Published

1992

7. Comparison of steady‐state and perturbative transport coefficients in TFTR

Author

E. J. Synakowski, Y. Kusama, D. K. Mansfield, Raffi Nazikian, G. Taylor, M. G. Bell, N. Bretz, H. Biglari, William Tang, A. T. Ramsey, S. S. Medley, Hyeon K. Park, David W. Johnson, P. C. Efthimion, Cris W. Barnes, G. Rewoldt, William Heidbrink, S. D. Scott, M. C. Zarnstorff, R. A. Hulse, Patrick Diamond, Brentley Stratton, Gregory W. Hammett, and S. J. Zweben

Subjects

Fluid Flow and Transfer Processes, Physics, Tokamak, Steady state, Transport coefficient, Computational Mechanics, General Physics and Astronomy, Plasma, Condensed Matter Physics, law.invention, Ion, Nuclear physics, Mechanics of Materials, law, Nuclear fusion, Tokamak Fusion Test Reactor, Beam (structure)

Abstract

Steady‐state and perturbative transport analysis are complementary techniques for the study of transport in tokamaks. These techniques are applied to the investigation of auxiliary‐heated L‐mode and supershot plasmas in the tokamak fusion test reactor (TFTR) [R. J. Hawryluk et al., Plasma Physics and Controlled Nuclear Fusion Research, Proceedings of the 11th International Conference, Kyoto, 1986 (IAEA, Vienna, 1987), Vol. 1, p. 51.]. In the L mode, both steady‐state and perturbative transport measurements reveal a strong temperature dependence that is consistent with electrostatic microinstability theory and the degradation of confinement with neutral beam power. Steady‐state analysis of the ion heat and momentum balance in supershots indicates a reduction and a significant weakening of the power‐law dependence on the transport in the center of the discharge.

Published

1991

8. High‐Qplasmas in the TFTR tokamak

Author

R. Boivin, J. R. Wilson, S. J. Kilpatrick, K. M. McGuire, E.D. Fredrickson, M. H. Redi, A. T. Ramsey, P. H. LaMarche, M. Ulrickson, J. E. Stevens, L. C. Johnson, D.C. McCune, David W. Johnson, J. L. Terry, J. H. Kamperschroer, A.C. Janos, J. Hosea, S. von Goeler, R.J. Hawryluk, H. Hsuan, Dale Meade, B.P. LeBlanc, D.K. Mansfield, M. C. Zarnstorff, E. J. Synakowski, J. Timberlake, M. G. Bell, D. R. Mikkelsen, J. D. Strachan, R.V. Budny, D. L. Jassby, F. C. Jobes, M. Williams, Hyeon K. Park, S. S. Medley, R. M. Wieland, E.S. Marmar, P. C. Efthimion, C. Kieras‐Phillips, G. Taylor, Kenneth M. Young, D. Mueller, K. W. Hill, S. J. Zweben, J.A. Snipes, Steven Sabbagh, C.E. Bush, S. Pitcher, B. C. Stratton, H. F. Dylla, S.F. Paul, Cris W. Barnes, S. D. Scott, N. L. Bretz, D. K. Owens, H. H. Towner, K. L. Wong, and Manfred Bitter

Subjects

Fluid Flow and Transfer Processes, Physics, Tokamak, Computational Mechanics, General Physics and Astronomy, Plasma, Fusion power, Condensed Matter Physics, law.invention, Nuclear physics, Mechanics of Materials, law, Limiter, Neutron source, Electron temperature, Neutron, Atomic physics, Tokamak Fusion Test Reactor

Abstract

In the Tokamak Fusion Test Reactor (TFTR) [Plasma Phys. Controlled Fusion 26, 11 (1984)], the highest neutron source strength Sn and D–D fusion power gain QDD are realized in the neutral‐beam‐fueled and heated ‘‘supershot’’ regime that occurs after extensive wall conditioning to minimize recycling. For the best supershots, Sn increases approximately as P1.8b. The highest‐Q shots are characterized by high Te (up to 12 keV), Ti (up to 34 keV), and stored energy (up to 4.7 MJ), highly peaked density profiles, broad Te profiles, and lower Zeff. Replacement of critical areas of the graphite limiter tiles with carbon‐fiber composite tiles and improved alignment with the plasma have mitigated the ‘‘carbon bloom.’’ Wall conditioning by lithium pellet injection prior to the beam pulse reduces carbon influx and particle recycling. Empirically, QDD increases with decreasing pre‐injection carbon radiation, and increases strongly with density peakedness [ne(0)/〈ne〉] during the beam pulse. To date, the best fusion resu...

Published

1991

9. High poloidal beta equilibria in the Tokamak Fusion Test Reactor limited by a natural inboard poloidal field null

Author

B. C. Stratton, A.C. Janos, R. M. Wieland, R.V. Budny, S.P. Hirshman, R.J. Hawryluk, Yoshio Nagayama, M. C. Zarnstorff, Steven Sabbagh, R. A. Gross, S.C. Jardin, R.E. Bell, Jay Kesner, K. M. McGuire, Michael E. Mauel, A. T. Ramsey, J. Manickam, M. S. Chance, E.D. Fredrickson, M. Okabayashi, Manfred Bitter, D.C. McCune, P. C. Efthimion, S. S. Medley, G. Taylor, D. L. Jassby, D. Mueller, N. L. Bretz, E.S. Marmar, J.L. Terry, G.A. Navratil, Hyeon K. Park, D. K. Owens, R. Hatcher, M. G. Bell, C.E. Bush, and E. J. Synakowski

Subjects

Fluid Flow and Transfer Processes, Physics, Tokamak, Computational Mechanics, General Physics and Astronomy, Magnetic confinement fusion, Fusion power, Condensed Matter Physics, Neutral beam injection, law.invention, Bootstrap current, Nuclear physics, Mechanics of Materials, law, Beta (plasma physics), Nuclear fusion, Atomic physics, Tokamak Fusion Test Reactor

Abstract

Recent operation of the Tokamak Fusion Test Reactor (TFTR) [Plasma Phys. Controlled Nucl. Fusion Research 1, 51 (1986)] has produced plasma equilibria with values of Λ≡βp eq+li/2 as large as 7, eβp dia≡2μ0e〈p⊥〉/〈〈Bp〉〉2 as large as 1.6, and Troyon normalized diamagnetic beta [Plasma Phys. Controlled Fusion 26, 209 (1984); Phys. Lett. 110A, 29 (1985)], βNdia≡108〈βt⊥〉aB0/Ip as large as 4.7. When eβp dia≳1.25, a separatrix entered the vacuum chamber, producing a naturally diverted discharge that was sustained for many energy confinement times, τE. The largest values of eβp and plasma stored energy were obtained when the plasma current was ramped down prior to neutral beam injection. The measured peak ion and electron temperatures were as large as 24 and 8.5 keV, respectively. Plasma stored energy in excess of 2.5 MJ and τE greater than 130 msec were obtained. Confinement times of greater than 3 times that expected from L‐mode predictions have been achieved. The fusion power gain QDD reached a value of 1.3×10−...

Published

1991

10. Experiments utilizing ion cyclotron range of frequencies heating on the TFTR tokamak

Author

B. C. Stratton, Manfred Bitter, Stewart Zweben, G. L. Schmidt, M. G. Bell, D. L. Jassby, E. J. Synakowski, D.K. Mansfield, E.D. Fredrickson, D. Mueller, M. C. Zarnstorff, Hyeon K. Park, J. E. Stevens, R. Boivin, S. D. Scott, G. J. Greene, M. Ono, S. S. Medley, J. C. Hosea, G. Taylor, K. W. Hill, H. Hsuan, David W. Johnson, F. C. Jobes, D. K. Owens, C. K. Phillips, James R. Wilson, D. Hoffman, M. Hughes, A.C. Janos, Gregory W. Hammett, K. M. McGuire, M. Ulrickson, M. W. Phillips, A. T. Ramsey, Yoshio Nagayama, and K. L. Wong

Subjects

Fluid Flow and Transfer Processes, Physics, Range (particle radiation), Tokamak, Cyclotron, Computational Mechanics, General Physics and Astronomy, Plasma, Sawtooth wave, Condensed Matter Physics, Neutral beam injection, law.invention, Ion, Mechanics of Materials, law, Nuclear fusion, Atomic physics

Abstract

A variety of experiments have been performed on the TFTR tokamak [Wilson et al., Plasma Physics and Controlled Nuclear Fusion Research 1988 (IAEA, Vienna, 1989), Vol. 1, p. 691] utilizing ion cyclotron range of frequencies (ICRF) heating. Of special interest has been the insight into plasma performance gained by utilizing a different heating scheme other than the usual neutral beam injection (NBI). Utilizing ICRF heating allows control over the power deposition profile independent of the plasma fueling profile. In addition, by varying the minority concentration the power split between ion and electron heating can be varied. Confinement has been examined in high recycling gas fueled discharges, low recycling supershot plasmas, and peaked density pellet fueled discharges. Global confinement is found not to be affected by the method or localization of plasma heating, but the calculated local diffusivities vary with the power deposition profile to yield similar global values. In addition, sawtooth stabilizati...

Published

1991

11. Correlations of heat and momentum transport in the TFTR tokamak

Author

S. D. Scott, M. C. Zarnstorff, G. Schilling, S. Yoshikawa, Einar Hinnov, A. C. Janos, E. J. Synakowski, B. Grek, K. L. Wong, R. Little, L. C. Johnson, D. K. Owens, H. H. Towner, K. P. Jaehnig, S. J. Zweben, Y. Nagayama, M. Williams, G. L. Schmidt, R. M. Wieland, H. F. Dylla, J. A. Murphy, David W. Johnson, E. Mazzucato, A. Cavallo, K. M. Young, J. Timberlake, A. T. Ramsey, Samuel Cohen, H. Hsuan, Dale Meade, T. K. Chu, G. Taylor, A. B. Erhrardt, B. LeBlanc, N. Bretz, K. W. Hill, D. K. Mansfield, J.F. Schivell, R. A. Hulse, Cris W. Barnes, C. Kieras‐Phillips, S. L. Davis, D. H. McNeill, P. H. LaMarche, D.L. Jassby, G. Greene, L. R. Grisham, S. von Goeler, Hyeon K. Park, Harold P. Furth, D. R. Mikkelsen, William Tang, M. H. Redi, M. Ulrickson, P. Colestock, Dennis M. Manos, W. Stodiek, P. C. Efthimion, R. Boivin, R. J. Hawryluk, S. S. Medley, V. Arunasalam, J. R. Wilson, P. H. Rutherford, A. L. Roquemore, R. B. Howell, Robert James Goldston, R. J. Fonck, Gregory W. Hammett, M. G. Bell, K. McGuire, R. W. Motley, R. Kaita, R. Nazakian, Robert Budny, C. E. Bush, D. C. McCune, M. McCarthy, J. Hosea, H. W. Hendel, D. Dimock, D. J. Hoffman, E.D. Fredrickson, J. E. Stevens, D. Mueller, Brentley Stratton, Manfred Bitter, S. J. Kilpatrick, and F. C. Jobes

Subjects

Fluid Flow and Transfer Processes, Physics, Tokamak, Momentum transfer, Computational Mechanics, General Physics and Astronomy, Plasma, Condensed Matter Physics, Neutral beam injection, law.invention, Nuclear physics, Momentum, Physics::Plasma Physics, Mechanics of Materials, law, Electron temperature, Tokamak Fusion Test Reactor, Beam (structure)

Abstract

Measurements of the toroidal rotation speed vφ(r) driven by neutral beam injection in tokamak plasmas and, in particular, simultaneous profile measurements of vφ, Ti, Te, and ne, have provided new insights into the nature of anomalous transport in tokamaks. Low‐recycling plasmas heated with unidirectional neutral beam injection exhibit a strong correlation among the local diffusivities, χφ≊χi>χe. Recent measurements have confirmed similar behavior in broad‐density L‐mode plasmas. These results are consistent with the conjecture that electrostatic turbulence is the dominant transport mechanism in the tokamak fusion test reactor tokamak (TFTR) [Phys. Rev. Lett. 58, 1004 (1987)], and are inconsistent with predictions both from test‐particle models of strong magnetic turbulence and from ripple transport. Toroidal rotation speed measurements in peaked‐density TFTR ‘‘supershots’’ with partially unbalanced beam injection indicate that momentum transport decreases as the density profile becomes more peaked. In hi...

Published

1990

12. High‐beta operation and magnetohydrodynamic activity on the TFTR tokamak

Author

M. Williams, P. C. Efthimion, P. H. Rutherford, T. K. Chu, K. McGuire, M. H. Redi, Robert Budny, M. Ulrickson, R. Kaita, W. Stodiek, G. L. Schmidt, D. K. Mansfield, G. Gammel, A. Cavallo, H. Hsuan, K. L. Wong, Manfred Bitter, J. Timberlake, Stewart Zweben, F. C. Jobes, C. Kieras‐Phillips, E. Mazzucato, E. J. Synakowski, Hyeon K. Park, Einar Hinnov, H. W. Hendel, D.L. Jassby, Y. Nagayama, Samuel A. Cohen, S. J. Kilpatrick, G. Greene, D. Monticello, P. Colestock, R. B. Howell, Robert James Goldston, G. Schilling, R. A. Hulse, A. L. Roquemore, M. McCarthy, N. Bretz, D. J. Hoffman, S. von Goeler, S. D. Scott, S. Pitcher, Gregory W. Hammett, M. C. Zarnstorff, D. R. Nazakian, R. M. Wieland, V. Arunasalam, E.D. Fredrickson, Harold P. Furth, C. E. Bush, J. A. Murphy, J.F. Schivell, William Tang, E. B. Neischmidt, M. G. Bell, J. E. Stevens, A. T. Ramsey, P. H. LaMarche, D. R. Mikkelsen, D. Mueller, R. J. Hawryluk, Brentley Stratton, S. S. Medley, J. Sinnis, Dennis M. Manos, J. R. Wilson, S. L. Davis, B. LeBlanc, David W. Johnson, Dale Meade, G. Taylor, D. Dimock, L. C. Johnson, D. K. Owens, H. H. Towner, W. Park, K. W. Hill, R. W. Motley, A. B. Ehrhrardt, Cris W. Barnes, H. F. Dylla, R. J. Fonck, A. C. Janos, D. H. McNeill, L. R. Grisham, M. C. McCune, B. Grek, Masaaki Yamada, K. M. Young, S. Yoshikawa, J.C. Hosea, and R. Boivin

Subjects

Fluid Flow and Transfer Processes, Physics, Tokamak, Computational Mechanics, General Physics and Astronomy, Atmospheric-pressure plasma, Magnetic reconnection, Plasma, Condensed Matter Physics, law.invention, Mechanics of Materials, law, Beta (plasma physics), Nuclear fusion, Magnetohydrodynamics, Atomic physics, Pressure gradient

Abstract

Magnetohydrodynamic (MHD) activity within three zones (core, half‐radius, and edge) of TFTR [Plasma Physics and Controlled Nuclear Fusion Research 1986 (IAEA, Vienna, 1987), Vol. 1, p. 51] tokamak plasmas are discussed. Near the core of the plasma column, sawteeth are often observed. Two types of sawteeth are studied in detail; one with complete, and the other with incomplete, magnetic reconnection. Their characteristics are determined by the shape of the q profile. Near the half‐radius the m/n=3/2 and 2/1 resistive ballooning modes are found to correlate with a beta collapse. The pressure and the pressure gradient at the mode rational surface are found to play an important role in stability. MHD activity is also studied at the plasma edge during limiter H modes. The edge localized modes (ELM’s) are found to have a precursor mode with a frequency between 50–200 kHz and a mode number m/n=1/0. The mode does not show a ballooning structure. While these instabilities have been studied on many other machines, ...

Published

1990