Your search keyword '"J. J. Zielinski"' showing total 11 results

1. Drift‐wave‐like density fluctuations in the Advanced Toroidal Facility (ATF) torsatron

Author

G. L. Bell, R. A. Langley, John B Wilgen, Dongkyu Lee, G. R. Hanson, M.J. Saltmarsh, R. C. Goldfinger, R. A. Dory, T.S. Bigelow, S.C. Aceto, T.C. Jernigan, G.R. Dyer, K. A. Sarksyan, J. F. Lyon, David A Rasmussen, J.L. Dunlap, J. H. Harris, Michael Shats, Larry R. Baylor, J. J. Zielinski, J.D. Bell, Donald P. Hutchinson, K.L. Vander Sluis, A.C. England, Masakatsu Murakami, R.J. Colchin, R. K. Richards, K. M. Likin, J. E. Simpkins, A. L. Qualls, R.C. Isler, and Cheng Ma

Subjects

Physics, Tokamak, Toroid, Magnetic confinement fusion, Electron, Radius, Plasma, Condensed Matter Physics, law.invention, Magnetic field, Physics::Plasma Physics, law, Plasma diagnostics, Atomic physics

Abstract

Density fluctuations in low‐collisionality, low‐beta (β∼0.1%), currentless plasmas produced with electron cyclotron heating (ECH) in the Advanced Toroidal Facility (ATF) torsatron [Fusion Technol. 10, 179 (1986)] have been studied using a 2 mm microwave scattering diagnostic. Pulsed gas puffing is used to produce transient steepening of the density profile from its typically flat shape; this leads to growth in the density fluctuations when the temperature and density gradients both point in the same direction in the confinement region. The wave number spectra of the fluctuations that appear during this perturbation have a maximum at higher k⊥ρs (∼1) than is typically seen in tokamaks. The in–out asymmetry of the fluctuations along the major radius correlates with the distribution of confined trapped particles expected for the ATF magnetic field geometry. During the perturbation, the relative level of the density fluctuations in the confinement region (integrated over normalized minor radii ρ from 0.5 to 0...

Published

1995

2. Fluctuation and modulation transport studies in the Advanced Toroidal Facility (ATF) torsatron*

Author

P. K. Mioduszewski, A.C. England, H. Ji, R.J. Colchin, K. L. Vander Sluis, T. D. Shepard, J.D. Bell, C. E. Thomas, T. C. Jernigan, R. F. Gandy, K. A. Sarksyan, J. E. Simpkins, James A. Rome, Hiroshi Yamada, R. K. Richards, M. R. Wade, Hiroyuki Okada, K. M. Likin, J. J. Zielinski, R. H. Goulding, S. C. Aceto, G.L. Bell, D.B. Batchelor, D. P. Hutchinson, Dongkyu Lee, M. Sato, R.C. Isler, R. A. Dory, W.R. Wing, M. Murakami, G.R. Dyer, R. C. Goldfinger, A. L. Qualls, E.C. Crume, S. Hiroe, S. Paul, Larry R. Baylor, S.P. Hirshman, David A Rasmussen, N. Dominguez, H. Kaneko, M. M. Menon, G. R. Hanson, H.C. Howe, J.C. Glowienka, J.L. Dunlap, Benjamin A. Carreras, J. G. Schwelberger, Cheng Ma, Taner Uckan, T.S. Bigelow, O. Motojima, M. Kwon, M. J. Saltmarsh, R. A. Langley, John B Wilgen, L.D. Horton, J. H. Harris, L. M. Kovrizhnykh, C. Hidalgo, M. G. Shats, Ker-Chung Shaing, and J. F. Lyon

Subjects

Fluid Flow and Transfer Processes, Physics, Electron density, Scattering, Computational Mechanics, Cyclotron resonance, General Physics and Astronomy, Electron, Collisionality, Condensed Matter Physics, Electron cyclotron resonance, Physics::Plasma Physics, Mechanics of Materials, Beta (plasma physics), Atomic physics, Dimensionless quantity

Abstract

The Advanced Toroidal Facility (ATF) torsatron [Fusion Technol. 10, 179 (1986)] has completed experiments focusing on microwave scattering measurements of density fluctuations and transport studies utilizing the modulation of dimensionless parameters. Microwave scattering measurements of electron density fluctuations in the core of low‐collisionality electron cyclotron heated (ECH) plasmas show features that might be evidence of trapped electron instabilities. Starting from gyro‐Bohm scaling, the additional dependence of confinement on the dimensionless parameters ν* and β (collisionality and beta) has been investigated by modulating each of these parameters separately, revealing the additional favorable dependence, τE∝τgBν*−0.18β+0.3.

Published

1993

3. Insituanalyzer calibration methods for heavy ion beam probes installed on stellarator‐like devices

Author

J. J. Zielinski, S. C. Aceto, J. G. Schwelberger, J. C. Glowienka, Kenneth A. Connor, A. Carnevali, and J. F. Lewis

Subjects

Materials science, Ion beam, business.industry, Plasma, Ion gun, law.invention, Optics, Electromagnetic coil, law, Calibration, Plasma diagnostics, Atomic physics, business, Instrumentation, Stellarator, Beam (structure)

Abstract

An absolute calibration of an installed heavy ion beam probe (HIBP) energy analyzer is possible by detecting secondary ions that come from a source at a known location that is maintained at a known potential. It is also necessary that the magnetic field that exists during the calibration be the same magnetic field that exists when a plasma is present. These conditions can be met on stellarators, heliotrons, and torsatrons, which produce their magnetic configurations with external coil sets. Since no internal plasma current is required, suitable sources for producing secondary ions by interaction with the primary beam can be placed inside the vacuum vessels of these devices at known locations. Secondary ions can be produced by the interaction of the primary beam with thin films, gas box probes, electron beams, or neutral gas filling the vacuum vessel. Details of a spherical mesh probe that combines the advantages of several of these methods are given.

Published

1992

4. The ATF heavy ion beam probe (invited)

Author

A. Carnevali, S. C. Aceto, J. J. Zielinski, Kenneth A. Connor, J. G. Schwelberger, and J. C. Glowienka

Subjects

Physics, Electron density, Electric field, Plasma diagnostics, Plasma, Electric potential, Atomic physics, Instrumentation, Charged particle, Beam (structure), Computational physics, Magnetic field

Abstract

A heavy ion beam probe (HIBP) has been implemented on the ATF torsatron at Oak Ridge National Laboratory with the primary goal of providing direct measurements of the plasma potential radial profile and thus of the radial electric field. The complex ATF geometry and magnetic field structure presented a diagnostic environment more challenging than that found on previous beam probe systems. Particular attention has therefore been given to in situ system alignment and control capabilities. Measurements of electric potential profiles, electron density profiles, electron density fluctuations, and electric potential fluctuations have now been made with this system. Most of the data obtained were for ECH heated discharges, but we were also able to make measurements of a few NBI heated plasmas. In addition to our calibration techniques, we were able to establish a reasonable confidence level for the data obtained since we could identify the most important potential profile characteristics predicted by theory and ...

Published

1992

5. Effects of magnetic geometry, fluctuations, and electric fields on confinement in the Advanced Toroidal Facility

Author

M. G. Shats, Dongkyu Lee, J. F. Lyon, Benjamin A. Carreras, L.D. Horton, J. H. Harris, S. Hiroe, R.C. Isler, R. A. Dory, M.R. Wade, C. E. Thomas, Hiroshi Yamada, G.R. Hanson, R. F. Gandy, J. J. Zielinski, J.D. Bell, M. Sato, J.L. Dunlap, R. A. Langley, John B Wilgen, Hiroyuki Okada, Larry R. Baylor, J. G. Schwelberger, W.R. Wing, G. L. Bell, T.S. Bigelow, H. Ji, R.J. Colchin, J. E. Simpkins, J.C. Glowienka, S. C. Aceto, A. L. Qualls, G.R. Dyer, David A Rasmussen, M. Murakami, E.C. Crume, Cheng Ma, Taner Uckan, T. C. Jernigan, James A. Rome, A.C. England, S. Morimoto, K. M. Likin, and N. Dominguez

Subjects

Fluid Flow and Transfer Processes, Physics, Toroid, Condensed matter physics, Computational Mechanics, General Physics and Astronomy, Magnetic confinement fusion, Geometry, Electron, Condensed Matter Physics, Instability, Magnetic field, law.invention, Mechanics of Materials, law, Electric field, Limiter, Stellarator

Abstract

Recent experiments in the Advanced Toroidal Facility (ATF) [Fusion Technol. 10, 179 (1986)] have been directed toward investigations of the basic physics mechanisms that control confinement in this device. Measurements of the density fluctuations throughout the plasma volume have provided indications for the existence of theoretically predicted dissipative trapped electron and resistive interchange instabilities. These identifications are supported by results of dynamic configuration scans of the magnetic fields during which the magnetic well volume, shear, and fraction of confined trapped particles are changed continuously. The influence of magnetic islands on the global confinement has been studied by deliberately applying error fields which strongly perturb the nested flux‐surface geometry, and the effects of electric fields have been investigated by means of biased limiter experiments.

Published

1992

6. Recent advances in heavy ion beam probe diagnostics (invited)

Author

Kenneth A. Connor, J. F. Lewis, R. L. Hickok, Abdelhamid Ouroua, S. C. Aceto, J. G. Schatz, P. M. Schoch, J. W. Heard, P. E. McLaren, J. G. Schwelberger, J. J. Zielinski, T. P. Crowley, and V. Simcic

Subjects

Physics, Tokamak, Charged particle, Computational physics, law.invention, Magnetic field, law, Wavenumber, Plasma diagnostics, Magnetic potential, Electric potential, Atomic physics, Magnetohydrodynamics, Instrumentation

Abstract

Heavy ion beam probes (HIBPs) have proven to be a unique tool for measuring fluctuations and particle transport in tokamaks. They have been used to measure fluctuations in density, electric potential, and magnetic vector potential. The density and potential fluctuation measurements have determined the particle flux due to electrostatic turbulence in the TEXT and ISX‐B tokamaks. In these measurements, the frequency spectra (0–500 kHz) of the phase between density and potential, the wave numbers of the fluctuations, and the fluctuation level are obtained. Three topics are discussed in this paper. We present measurements of magnetic fluctuations during MHD activity using the TEXT HIBP. Analysis of these measurements indicates that the diagnostic is primarily sensitive to the local value of Aφ in the sample volume unless the local Aφ is small. In addition, we discuss instrumental effects associated with wave number measurements. We will discuss the effects of sample volume size on the wave number measurements...

Published

1990

7. Overview of results from the ATF torsatron

Author

H.C. Howe, R. H. Goulding, Hiroshi Yamada, P. L. Shaw, J. F. Lyon, R.J. Colchin, W.R. Wing, J. E. Simpkins, S. Sudo, G.R. Dyer, G. R. Haste, J.L. Dunlap, David A Rasmussen, D.L. Hillis, R.C. Isler, Robert Noel Morris, Dongkyu Lee, A.C. England, W. A. Gabbard, J. J. Zielinski, T. D. Shepard, M. R. Wade, P. K. Mioduszewski, R. A. Langley, G.H. Neilson, John B Wilgen, J. W. Halliwell, G.R. Hanson, P. S. Rogers, M. Murakami, E.C. Crume, S. Hiroe, L.D. Horton, J. H. Harris, T.S. Bigelow, C. Hidalgo‐Vera, T. C. Jernigan, G. L. Bell, M. Kwon, J. W. Lue, E. Anabitarte, Cheng Ma, Taner Uckan, P. W. Fisher, A. L. Qualls, C. E. Thomas, D. P. Hutchinson, F.S.B. Anderson, J.D. Bell, M.M. Menon, and J.C. Glowienka

Subjects

Fluid Flow and Transfer Processes, Physics, Cyclotron, Computational Mechanics, General Physics and Astronomy, Radius, Plasma, Electron, Condensed Matter Physics, Neutral beam injection, law.invention, Bootstrap current, Nuclear physics, Mechanics of Materials, law, Atomic physics, Electric current, Stellarator

Abstract

Experiments involving plasma improvement, confinement scaling, bootstrap currents, and edge fluctuations have been carried out in the Advanced Toroidal Facility (ATF) torsatron [Fusion Technol. 10, 179 (1986)]. Average densities ne≤9×1019 m−3 have been obtained, with global energy confinement times τ*E≤20 msec. Confinement times generally follow the stellarator/torsatron empirical scaling law, τSL =0.17×P−0.58n0.69eB0.84a2R0.75 (with τSL in seconds, power P in megawatts, density ne in 1020 m−3, and plasma radius a and major radius R in meters). Gas injection during neutral beam injection (NBI) causes increases in ne, so that τ*E does not decrease during NBI. Edge plasma fluctuations are found to exhibit a mode change near the peak of the energy confinement time. Plasma currents observed during electron cyclotron heating have been identified as bootstrap currents.

Published

1990

8. Electron density profile measurement with a heavy ion beam probe

Author

David A Rasmussen, M. Murakami, T. Uckan, J. J. Zielinski, R.C. Isler, J. G. Schwelberger, Cheng Ma, L. A. Baylor, A.C. England, S. C. Aceto, and Kenneth A. Connor

Subjects

Electron density, Materials science, Toroid, Electron temperature, Plasma diagnostics, Plasma, Atomic physics, Instrumentation, Charged particle, Line (formation), Ion

Abstract

The feasibility of electron density profile measurements using a heavy ion beam probe in high‐temperature plasmas has been demonstrated earlier [J. Schwelberger et al., Bull. Am. Phys. Soc. 36, 2292 (1991); Yu. N. Dnestrovskij et al., Sov. J. Plasma Phys. 12, 130 (1986)]. Two algorithms were developed to obtain density profiles from the heavy ion beam probe on the Advanced Toroidal Facility (ATF). A comparison of the algorithms is presented with a detailed study of the errors involved in the measurements. The errors can be due to uncertainties in cross sections, electron temperature, the line average density measurement, and the ion trajectory calculations. The heavy ion beam probe density profile measurement is not very susceptible to errors as long as the electron temperature stays above 30 eV. If the electron temperature is below this value, a small uncertainty in the temperature introduces a large error in the density. Also, important for a good density profile measurement is the calculation of the co...

Published

1992

9. Use of a heavy ion beam probe to measure the plasma potential on the Advanced Toroidal Facility

Author

J. G. Schwelberger, Kenneth A. Connor, J. J. Zielinski, and S. C. Aceto

Subjects

Electron density, Materials science, Nuclear engineering, Plasma, Charged particle, Ion, law.invention, Nuclear physics, Physics::Plasma Physics, law, Physics::Accelerator Physics, Plasma diagnostics, Electric potential, Instrumentation, Beam (structure), Stellarator

Abstract

During the last operational period of ATF, a heavy ion beam probe was used to make measurements of the plasma potential, potential fluctuations, and electron density fluctuations. Due to the limited operational time and resources these measurements were made primarily on ECH plasmas, although some neutral beam heated plasma data were taken. The general results of these measurements and a discussion of the possible mechanisms which could cause uncertainties in the results will be given. The diagnostic method will be outlined with an emphasis on issues related to the operation of a beam probe in a stellarator environment.

Published

1992

10. Energy analyzer for the ATF heavy ion beam probe

Author

P. E. McLaren, S. C. Aceto, J. G. Schatz, Kenneth A. Connor, G. H. Henkel, and J. J. Zielinski

Subjects

Spectrum analyzer, Materials science, Field (physics), business.industry, Emphasis (telecommunications), Electrostatics, Magnetic field, Optics, Calibration, Plasma diagnostics, Atomic physics, business, Instrumentation, Energy (signal processing)

Abstract

The energy analyzer for the ATF heavy ion beam probe has been built and tested. Because the analyzer will be required to operate in fields as high as 550 G on ATF and since calibration of the analyzer in the absence of a field will not be possible once it is installed, a special emphasis has been made to characterize its performance on a test stand. In order to ensure accurate knowledge of the analyzer geometric parameters, it was assembled with the aid of a coordinate axis measuring machine. The results of these tests are presented and a comparison to ideal analyzer performance is made.

Published

1990

11. ATF heavy ion beam probe: Installation and initial operation

Author

D. K. Lee, W. R. DeVan, D. T. Fehling, J. J. Zielinski, A. Carnevali, G. H. Henkel, K. D. St. Onge, Kenneth A. Connor, J. F. Lewis, S. C. Aceto, and J. C. Glowienka

Subjects

Spectrum analyzer, Heavy ion beam, Beamline, Control system, Nuclear engineering, Environmental science, Plasma diagnostics, Plasma, Atomic physics, Instrumentation, Electromagnetic interference, Magnetic field

Abstract

Installation of the HIBP on ATF began in the summer of 1988. All of the major hardware components have now been installed. The initial operation of the diagnostic has begun amid the final stages of testing and control system integration. The existence of significant magnetic fields and gradients outside of the main plasma volume and fully three‐dimensional particle trajectories have raised several interesting issues during the design, assembly, alignment, and operation of the beamline and analyzer. The diagnostic must function in a challenging environment. It must perform satisfactorily despite electrical interference from several nearby sources, pressure excursions caused by gas puffing, and UV/plasma loading.

Published

1990