Your search keyword '"Eli Parke"' showing total 10 results

1. Fast ion transport in the quasi-single helical reversed-field pinch

Author

J. Boguski, Jay Anderson, Juhyung Kim, Donald A. Spong, Eli Parke, M. Gobbin, Jan Egedal, and P. J. Bonofiglo

Subjects

Ions, Physics, Electron density, Reversed field pinch, Geometry, Equilibrium reconstruction, Condensed Matter Physics, 01 natural sciences, Madison Symmetric Torus, Resonance (particle physics), Density perturbation, 010305 fluids & plasmas, Computational physics, Ion, Pinch effect, Physics::Plasma Physics, 0103 physical sciences, Energetic particles, Pinch, Neutron, 010306 general physics, Neutral particle, Repair

Abstract

The reversed-field pinch (RFP) can spontaneously transition from an axisymmetric magnetic topology to a 3D-helical geometry. Investigations on fast ion transport associated with energetic particle driven Alfven instabilities, tearing mode induced stochasticity, and neoclassical effects have been performed on the Madison Symmetric Torus. STELLGAP produced shear-Alfven continua seeded with V3FIT 3D-equilibrium reconstructions describe the response of Alfvenic bursting activity as a direct consequence of the equilibrium change on the fast ion resonance. Far infrared interferometry resolved electron density perturbations associated with the bursts provide a spatial measurement of the mode structure and support the reconstructions. The bursts produce no global resonant fast ion transport; however, their disappearance at a high core-resonant amplitude implies other transport mechanisms at play. Neutral particle analysis and neutron signals suggest fast ion losses at sufficient core tearing mode strength, supporting the lack of Alfvenic activity. The guiding-center code ORBIT corroborates rapid fast ion loss times in the helical state largely as a consequence of remnant tearing modes. Additionally, ORBIT simulations demonstrate little neoclassical enhancement of particle transport. While superbanana orbits may exist, the growth in the core-resonant fast ion island and the associated secondary mode overlap govern the largest transport process, leading to robust fast ion losses in the 3D-RFP.The reversed-field pinch (RFP) can spontaneously transition from an axisymmetric magnetic topology to a 3D-helical geometry. Investigations on fast ion transport associated with energetic particle driven Alfven instabilities, tearing mode induced stochasticity, and neoclassical effects have been performed on the Madison Symmetric Torus. STELLGAP produced shear-Alfven continua seeded with V3FIT 3D-equilibrium reconstructions describe the response of Alfvenic bursting activity as a direct consequence of the equilibrium change on the fast ion resonance. Far infrared interferometry resolved electron density perturbations associated with the bursts provide a spatial measurement of the mode structure and support the reconstructions. The bursts produce no global resonant fast ion transport; however, their disappearance at a high core-resonant amplitude implies other transport mechanisms at play. Neutral particle analysis and neutron signals suggest fast ion losses at sufficient core tearing mode strength, suppor...

Published

2019

2. Thomson scattering systems on C-2W field-reversed configuration plasma experiment

Author

M. C. Thompson, Eli Parke, D. Fallah, K. Zhai, Tania Schindler, A. Ottaviano, J. Wells, Tae Team, and H. Zhang

Subjects

010302 applied physics, Physics, Jet (fluid), Thomson scattering, Electron, Plasma, 01 natural sciences, 010305 fluids & plasmas, Computational physics, Ion, Temporal resolution, 0103 physical sciences, Field-reversed configuration, Electron temperature, Instrumentation

Abstract

TAE Technologies' newly constructed C-2W experiment aims to improve the ion and electron temperatures in a sustained field-reversed configuration plasma. A suite of Thomson scattering systems has been designed and constructed for electron temperature and density profile measurements. The systems are designed for electron densities of 1 × 1012 cm-3 to 2 × 1014 cm-3 and temperature ranges from 10 eV to 2 keV. The central system will provide profile measurements of Te and ne at 16 radial locations from r = -9 cm to r = 64 cm with a temporal resolution of 20 kHz for 4 pulses or 1 kHz for 30 pulses. The jet system will provide profile measurements of Te and ne at 5 radial locations in the open field region from r = -5 cm to r = 15 cm with a temporal resolution of 100 Hz. The central system and its components have been characterized, calibrated, installed, and commissioned. A maximum-likelihood algorithm has been applied for data processing and analysis.

Published

2018

3. Characterization and calibration of the Thomson scattering diagnostic suite for the C-2W field-reversed configuration experiment

Author

A. Ottaviano, M. C. Thompson, Eli Parke, K. Zhai, Tania Schindler, Tae Team, and Erik Granstedt

Subjects

010302 applied physics, Physics, business.industry, Thomson scattering, Ranging, Plasma, Laser, 01 natural sciences, 010305 fluids & plasmas, law.invention, Numerical aperture, symbols.namesake, Optics, law, 0103 physical sciences, Calibration, symbols, Electron temperature, Rayleigh scattering, business, Instrumentation

Abstract

The new C-2W Thomson scattering (TS) diagnostic consists of two individual subsystems for monitoring electron temperature (Te) and density (ne): one system in the central region is currently operational, and the second system is being commissioned to monitor the open field line region. Validating the performance of the TS's custom designed system components and unique calibration of the detection system and diagnostic as a whole is crucial to obtaining high precision Te and ne profiles of C-2W's plasma. The major components include a diode-pumped Nd:YAG laser which produces 35 pulses at up to 20 kHz, uniquely designed collection lenses with a fast numerical aperture, and uniquely designed polychromators with filters sets to optimize a Te ranging from 10 eV to 2 keV. This paper describes the design principles and techniques used to characterize the main components of the TS diagnostic on C-2W, as well as the results of Rayleigh scattering calibrations performed for the whole system response.

Published

2018

4. Three dimensional equilibrium solutions for a current-carrying reversed-field pinch plasma with a close-fitting conducting shell

Author

J.J. Koliner, B. E. Chapman, D. L. Brower, J. Boguski, J. Duff, Mark Cianciosa, M.B. McGarry, James D. Hanson, Weixing Ding, Eli Parke, John Goetz, Lucas Morton, Jay Anderson, and D.J. Den Hartog

Subjects

Physics, Toroid, Reversed field pinch, Shell (structure), Plasma, Mechanics, Condensed Matter Physics, 01 natural sciences, Madison Symmetric Torus, 010305 fluids & plasmas, law.invention, Physics::Plasma Physics, law, 0103 physical sciences, Eddy current, Pinch, Atomic physics, Electric current, 010306 general physics

Abstract

In order to characterize the Madison Symmetric Torus (MST) reversed-field pinch (RFP) plasmas that bifurcate to a helical equilibrium, the V3FIT equilibrium reconstruction code was modified to include a conducting boundary. RFP plasmas become helical at a high plasma current, which induces large eddy currents in MST's thick aluminum shell. The V3FIT conducting boundary accounts for the contribution from these eddy currents to external magnetic diagnostic coil signals. This implementation of V3FIT was benchmarked against MSTFit, a 2D Grad-Shafranov solver, for axisymmetric plasmas. The two codes both fit Bθ measurement loops around the plasma minor diameter with qualitative agreement between each other and the measured field. Fits in the 3D case converge well, with q-profile and plasma shape agreement between two distinct toroidal locking phases. Greater than 60% of the measured n = 5 component of Bθ at r = a is due to eddy currents in the shell, as calculated by the conducting boundary model.

Published

2016

5. Fast ion confinement and stability in a neutral beam injected reversed field pinch

Author

L. Lin, D.J. Den Hartog, A. A. Ivanov, G. Fiksel, Mark Nornberg, J.J. Koliner, Vladimir Mirnov, Cary Forest, A. F. Almagri, Donald A. Spong, J. B. Titus, Eli Parke, S. Eilerman, Jay Anderson, Dongjian Liu, J.A. Reusch, S. V. Polosatkin, Vladimir I. Davydenko, J. Waksman, Yu. A. Tsidulko, J. S. Sarff, V. Belykh, Lucas Morton, and Hajime Sakakita

Subjects

Physics, education.field_of_study, Tokamak, Reversed field pinch, Population, Condensed Matter Physics, Madison Symmetric Torus, Charged particle, law.invention, Ion, Physics::Plasma Physics, law, Atomic physics, Neutral particle, education, Stellarator

Abstract

The behavior of energetic ions is fundamentally important in the study of fusion plasmas. While well-studied in tokamak, spherical torus, and stellarator plasmas, relatively little is known in reversed field pinch plasmas about the dynamics of fast ions and the effects they cause as a large population. These studies are now underway in the Madison Symmetric Torus with an intense 25 keV, 1 MW hydrogen neutral beam injector (NBI). Measurements of the time-resolved fast ion distribution via a high energy neutral particle analyzer, as well as beam-target neutron flux (when NBI fuel is doped with 3–5% D2) both demonstrate that at low concentration the fast ion population is consistent with classical slowing of the fast ions, negligible cross-field transport, and charge exchange as the dominant ion loss mechanism. A significant population of fast ions develops; simulations predict a super-Alfvenic ion density of up to 25% of the electron density with both a significant velocity space gradient and a sharp radial...

Published

2013

6. Neutral beam heating of a RFP plasma in MST

Author

Eli Parke, P. P. Deichuli, Jay Anderson, A. A. Ivanov, N. V. Stupishin, J.A. Reusch, J. Waksman, Vladimir I. Davydenko, Hajime Sakakita, Mark Nornberg, Gennady Fiksel, and Dongjian Liu

Subjects

Physics, Surface coating, Reversed field pinch, Physics::Plasma Physics, Pinch, Electron temperature, Plasma, Atomic physics, Condensed Matter Physics, Madison Symmetric Torus, Neutral beam injection, Beam (structure)

Abstract

Electron temperature is observed to rise due to neutral beam injection (NBI) in the Madison Symmetric Torus (MST). Heating is observed to be 100 ± 50 eV in the core of 200 kA plasmas. This is the first definitive measurement of auxiliary heating of a reversed-field pinch (RFP). This heating is consistent with a 1D classical model which was developed. This 1D model calculates the evolving thermal conductivity and ohmic power input profiles during enhanced confinement, and can calculate NBI deposition and classical fast ion diffusion and slowing. The predicted temperature change is consistent with measured beam heating both during and after enhanced confinement, which is consistent with previous observations that fast ions are well confined and behave roughly classically in the RFP.

Published

2012

7. Improvements to the calibration of the MST Thomson scattering diagnostic

Author

A. F. Falkowski, Lucas Morton, C.P. Kasten, J. Goglio, A. Plunkett, J.A. Reusch, M. T. Borchardt, D.J. Den Hartog, Eli Parke, H.D. Stephens, N. C. Hurst, and W. H. Harris

Subjects

Physics, Physics::Instrumentation and Detectors, business.industry, Thomson scattering, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Avalanche photodiode, Photodiode, law.invention, Responsivity, Optics, Operating temperature, law, Calibration, Measurement uncertainty, business, Instrumentation

Abstract

Calibration of the Madison Symmetric Torus Thomson scattering system has been refined to improve temperature fluctuation measurements. Multiple avalanche photodiodes have been directly calibrated for use as reference detectors during calibration, improving accuracy and ease of use. From the absolute calibration we calculate corrections to the gain for variation in detector operating temperature. We also measure the spatial uniformity of detector responsivity for several photodiodes, and present a method of accounting for non-uniformity in the calibration process. Finally, the gain and noise enhancement are measured at multiple wavelengths to improve temperature and uncertainty measurements.

Published

2012

8. Classical confinement and outward convection of impurity ions in the MST RFP

Author

Weixing Ding, Eli Parke, B. E. Chapman, Darren Craig, S. T. A. Kumar, K.J. Caspary, J. S. Sarff, R. M. Magee, D. L. Brower, L. Lin, Vladimir Mirnov, Mark Nornberg, S. Eilerman, J.A. Reusch, D.J. Den Hartog, and Gennady Fiksel

Subjects

Physics, Convection, Reversed field pinch, Physics::Plasma Physics, Impurity, Pinch, Plasma, Atomic physics, Collisionality, Condensed Matter Physics, Madison Symmetric Torus, Ion

Abstract

Impurity ion dynamics measured with simultaneously high spatial and temporal resolution reveal classical ion transport in the reversed-field pinch. The boron, carbon, oxygen, and aluminum impurity ion density profiles are obtained in the Madison Symmetric Torus [R. N. Dexter et al., Fusion Technol. 19, 131 (1991)] using a fast, active charge-exchange-recombination-spectroscopy diagnostic. Measurements are made during improved-confinement plasmas obtained using inductive control of tearing instability to mitigate stochastic transport. At the onset of the transition to improved confinement, the impurity ion density profile becomes hollow, with a slow decay in the core region concurrent with an increase in the outer region, implying an outward convection of impurities. Impurity transport from Coulomb collisions in the reversed-field pinch is classical for all collisionality regimes, and analysis shows that the observed hollow profile and outward convection can be explained by the classical temperature screening mechanism. The profile agrees well with classical expectations. Experiments performed with impurity pellet injection provide further evidence for classical impurity ion confinement.

Published

2012

9. Pulse-burst laser systems for fast Thomson scattering (invited)

Author

A. F. Falkowski, J.A. Reusch, H.D. Stephens, Eli Parke, P. E. Robl, M. T. Borchardt, J. R. Ambuel, W. S. Harris, D.J. Den Hartog, Y.M. Yang, and D. J. Holly

Subjects

Materials science, Thomson scattering, business.industry, chemistry.chemical_element, Insulated-gate bipolar transistor, Laser, Q-switching, Neodymium, Pockels effect, law.invention, Pulse (physics), Optical pumping, Optics, chemistry, law, business, Instrumentation

Abstract

Two standard commercial flashlamp-pumped Nd:YAG (YAG denotes yttrium aluminum garnet) lasers have been upgraded to "pulse-burst" capability. Each laser produces a burst of up to 15 2 J Q-switched pulses (1064 nm) at repetition rates of 1-12.5 kHz. Variable pulse-width drive (0.15-0.39 ms) of the flashlamps is accomplished by insulated gate bipolar transistor (IGBT) switching of electrolytic capacitor banks. Direct control of the laser Pockels cell drive enables optimal pulse energy extraction, and up to four 2 J laser pulses during one flashlamp pulse. These lasers are used in the Thomson scattering plasma diagnostic system on the MST reversed-field pinch to record the dynamic evolution of the electron temperature profile and temperature fluctuations. To further these investigations, a custom pulse-burst laser system with a maximum pulse repetition rate of 250 kHz is now being commissioned.

Published

2010

10. Determining the absolute efficiency of a delay line microchannel-plate detector using molecular dissociation

Author

A. M. Sayler, Itzik Ben-Itzhak, Pengqian Wang, B. Gaire, Nora G. Johnson, Eli Parke, K. D. Carnes, and M. Leonard

Subjects

Physics, Physics::Instrumentation and Detectors, business.industry, Detector, Breakup, Signal, Diatomic molecule, Dissociation (chemistry), Ion, Optics, Position (vector), Microchannel plate detector, business, Instrumentation

Abstract

We present a method to measure the absolute detection efficiency of a delay-line microchannel-plate detector using the breakup of diatomic molecular ions. This method provides the absolute total detection efficiency, as well as the individual efficiency for each signal of the detector. The method is based on the fact that molecular breakup always yields two hits on the detector, but due to finite detection efficiency some of these events are recorded as single particles while others are detected in pairs. We demonstrate the method by evaluating the detection efficiency for both timing and position signals of a delay-line detector using laser-induced dissociation of molecular ions. In addition, the detection efficiency as a function of position has been determined by dividing the detector into sectors.

Published

2007