Your search keyword '"J. S. Kinley"' showing total 9 results

1. Development of a three-wave far-infrared laser interferometry and polarimetry diagnostic system for the C-2W field-reversed configuration plasmas

Author

J. S. Kinley, Bihe Deng, J Castellanos, M. C. Thompson, G. Settles, M. Beall, M. Rouillard, Tae Team, A. Ottaviano, J. Wells, H K Leinweber, S Armstrong, P. Feng, Greg Snitchler, and S. Ziaei

Subjects

010302 applied physics, Physics, Reversed field pinch, business.industry, Far-infrared laser, Polarimetry, 01 natural sciences, Refraction, 010305 fluids & plasmas, symbols.namesake, Interferometry, Optics, Far infrared, 0103 physical sciences, Faraday effect, symbols, Plasma diagnostics, business, Instrumentation

Abstract

Great advancements in modern field-reversed configuration (FRC) experiments motivated the development of a 14-chord three-wave far infrared (FIR) laser interferometry and polarimetry diagnostic system, which can provide simultaneous high temporal resolution measurements of density and Faraday rotation profiles with high accuracy. The unique challenges facing FIR diagnostics in high beta FRC plasmas are the extremely small (

Published

2018

2. Improved Confinement of C-2 Field-Reversed Configuration Plasmas

Author

S. Primavera, K. Zhai, Ales Necas, Erik Trask, Deepak Gupta, R. Mendoza, E. Garate, Y. Song, Artem Smirnov, A. Sibley, Norman Rostoker, L. Sevier, J. S. Kinley, Hiroshi Gota, Bihe Deng, A. Van Drie, P. Feng, S. Putvinski, Sergey Korepanov, T. Valentine, Sangeeta Gupta, Jon Douglass, C. Hooper, Lothar Schmitz, J. K. Walters, M. Cordero, K. Knapp, M. C. Thompson, D. Q. Bui, K. D. Conroy, S. Aefsky, H. Y. Guo, Tae Team, M. Onofri, J. Romero, Nikolaus Rath, Y. Mok, W. Waggoner, Thomas Roche, Sean Dettrick, E. Granstedt, T. Tajima, J. H. Schroeder, Xiaokang Yang, A. Longman, M. Tuszewski, I. Allfrey, Michl Binderbauer, R. Clary, P. Yushmanov, R. M. Magee, N. Bolte, L. C. Steinhauer, D. Osin, Dan Barnes, and F. Ceccherini

Subjects

Nuclear and High Energy Physics, Materials science, Mechanical Engineering, chemistry.chemical_element, Plasma, Nuclear Energy and Engineering, chemistry, Getter, Field-reversed configuration, General Materials Science, Lithium, Atomic physics, Neutral density filter, Scaling, Civil and Structural Engineering

Abstract

C-2 is a unique, large compact-toroid (CT) device at Tri Alpha Energy that produces field-reversed configuration (FRC) plasmas by colliding and merging oppositely directed CTs. Significant progress has recently been made on C-2, achieving ~5 ms stable plasmas with a dramatic improvement in confinement, far beyond the prediction from the conventional FRC scaling. This stable, long-lived FRC plasma state is called the high-performance FRC (HPF) regime. The key approaches to achieve the HPF regime are as follows: (i) dynamic FRC formation by collision/merging of super-Alfvenic CTs, (ii) effective control of stability and transport by end-on plasma guns and neutral-beam (NB) injection, and (iii) active wall conditioning using titanium and lithium gettering systems. Moreover, further improvement in FRC confinement has been obtained with improved open-field-line plasma properties such as a lower fluctuation level, reduced transport rates in radial/axial directions, and lower background neutral density a...

Published

2015

3. Characterization of compact-toroid injection during formation, translation, and field penetration

Author

W. Waggoner, Thomas Roche, E. Garate, T. Matsumoto, J. S. Kinley, T. Tajima, T. Valentine, I. Allfrey, Tomohiko Asai, Michl Binderbauer, Hiroshi Gota, Junichi Sekiguchi, and M. Cordero

Subjects

Physics, Dense plasma focus, business.industry, Compact toroid, Injector, Plasma, Penetration (firestop), 01 natural sciences, 010305 fluids & plasmas, law.invention, Magnetic field, Optics, law, 0103 physical sciences, Physics::Accelerator Physics, Tomography, Atomic physics, Coaxial, 010306 general physics, business, Instrumentation

Abstract

We have developed a compact toroid (CT) injector system for particle refueling of the advanced beam-driven C-2U field-reversed configuration (FRC) plasma. The CT injector is a magnetized coaxial plasma gun (MCPG), and the produced CT must cross the perpendicular magnetic field surrounding the FRC for the refueling of C-2U. To simulate this environment, an experimental test stand has been constructed. A transverse magnetic field of ∼1 kG is established, which is comparable to the C-2U axial magnetic field in the confinement section, and CTs are fired across it. On the test stand we have been characterizing and studying CT formation, ejection/translation from the MCPG, and penetration into transverse magnetic fields.

Published

2016

4. The upgrade of the Thomson scattering system for measurement on the C-2/C-2U devices

Author

J. S. Kinley, Bihe Deng, K. Zhai, M. C. Thompson, and T. Schindler

Subjects

Physics, Electron density, Scattering, Thomson scattering, business.industry, Electron, Inelastic scattering, 01 natural sciences, Noise (electronics), 010305 fluids & plasmas, symbols.namesake, Optics, 0103 physical sciences, symbols, Plasma diagnostics, Rayleigh scattering, 010306 general physics, business, Instrumentation

Abstract

The C-2/C-2U Thomson scattering system has been substantially upgraded during the latter phase of C-2/C-2U program. A Rayleigh channel has been added to each of the three polychromators of the C-2/C-2U Thomson scattering system. Onsite spectral calibration has been applied to avoid the issue of different channel responses at different spots on the photomultiplier tube surface. With the added Rayleigh channel, the absolute intensity response of the system is calibrated with Rayleigh scattering in argon gas from 0.1 to 4 Torr, where the Rayleigh scattering signal is comparable to the Thomson scattering signal at electron densities from 1 × 1013 to 4 × 1014 cm−3. A new signal processing algorithm, using a maximum likelihood method and including detailed analysis of different noise contributions within the system, has been developed to obtain electron temperature and density profiles. The system setup, spectral and intensity calibration procedure and its outcome, data analysis, and the results of electron tem...

Published

2016

5. High sensitivity far infrared laser diagnostics for the C-2U advanced beam-driven field-reversed configuration plasmas

Author

J. H. Schroeder, M. C. Thompson, P. Feng, M. Beall, Hiroshi Gota, G. Settles, J. S. Kinley, and Bihe Deng

Subjects

Physics, Reversed field pinch, business.industry, Far-infrared laser, Polarimetry, Laser, 01 natural sciences, 010305 fluids & plasmas, law.invention, symbols.namesake, Interferometry, Optics, law, 0103 physical sciences, Faraday effect, symbols, Astronomical interferometer, Plasma diagnostics, 010306 general physics, business, Instrumentation

Abstract

A high sensitivity multi-channel far infrared laser diagnostics with switchable interferometry and polarimetry operation modes for the advanced neutral beam-driven C-2U field-reversed configuration (FRC) plasmas is described. The interferometer achieved superior resolution of 1 × 1016 m−2 at >1.5 MHz bandwidth, illustrated by measurement of small amplitude high frequency fluctuations. The polarimetry achieved 0.04° instrument resolution and 0.1° actual resolution in the challenging high density gradient environment with >0.5 MHz bandwidth, making it suitable for weak internal magnetic field measurements in the C-2U plasmas, where the maximum Faraday rotation angle is less than 1°. The polarimetry resolution data is analyzed, and high resolution Faraday rotation data in C-2U is presented together with direct evidences of field reversal in FRC magnetic structure obtained for the first time by a non-perturbative method.

Published

2016

6. Formation of hot, stable, long-lived field-reversed configuration plasmas on the C-2W device

Author

M. C. Thompson, R. Michel, Jon Douglass, M. Beall, S. Krause, D. Lieurance, Tomohiko Asai, Artem Smirnov, T. Matsumoto, A. A. Ivanov, N. Bolte, M. Meekins, K. Zhai, C. Finucane, E. Parke, V. Matvienko, Erik Trask, Zhihong Lin, C. Weixel, A. Van Drie, F. Ceccherini, Martin Griswold, M. Tuszewski, Roger Smith, J. Ufnal, M. Morehouse, H. Leinweber, R. M. Magee, Sergei Putvinski, A. Chirumamilla, E. Bomgardner, Deepak Gupta, Y. Song, Kevin Hubbard, S. Ziaei, M. Wollenberg, M. Slepchenkov, A. Dunaevsky, T. DeHaas, G. Snitchler, J. H. Schroeder, Ales Necas, E. Barraza, J.B. Titus, K. Galvin, E. A. Baltz, D. Osin, L. Sevier, Marco Onofri, M. Signorelli, J. S. Kinley, A. Ottaviano, Bihe Deng, P. Feng, J. Leuenberger, Ivan Isakov, D. Fallah, Calvin Lau, M. Nations, R. Andow, Xiaokang Yang, U. Guerrero, Ami DuBois, Vladimir Sokolov, J. K. Walters, J. Romero, R. Mendoza, D. Madura, A. Korepanov, D. Sheftman, W. Waggoner, Thomas Roche, Sean Dettrick, Hiroshi Gota, Tania Schindler, Saurabh Gupta, Ryan Clary, Peter Yushmanov, L. C. Steinhauer, A. Sibley, Erik Granstedt, Sergey Korepanov, Daniel Fulton, L. W. Schmitz, John Platt, Laura Galeotti, Toshiki Tajima, Y. Mok, T. Valentine, M. Madrid, I. Allfrey, and Michl Binderbauer

Subjects

Nuclear and High Energy Physics, Materials science, Compact toroid, Divertor, Pulse duration, Biasing, Plasma, Condensed Matter Physics, 01 natural sciences, Neutral beam injection, 010305 fluids & plasmas, 0103 physical sciences, Field-reversed configuration, Electron temperature, Atomic physics, 010306 general physics

Abstract

TAE Technologies' research is devoted to producing high temperature, stable, long-lived field-reversed configuration (FRC) plasmas by neutral-beam injection (NBI) and edge biasing/control. The newly constructed C-2W experimental device (also called "Norman") is the world's largest compact-toroid (CT) device, which has several key upgrades from the preceding C-2U device such as higher input power and longer pulse duration of the NBI system as well as installation of inner divertors with upgraded electrode biasing systems. Initial C-2W experiments have successfully demonstrated a robust FRC formation and its translation into the confinement vessel through the newly installed inner divertor with adequate guide magnetic field. They also produced dramatically improved initial FRC states with higher plasma temperatures (Te ~250+ eV; total electron and ion temperature g1.5 keV, based on pressure balance) and more trapped flux (up to ~15 mWb, based on rigid-rotor model) inside the FRC immediately after the merger of collided two CTs in the confinement section. As for effective edge control on FRC stabilization, a number of edge biasing schemes have been tried via open field-lines, in which concentric electrodes located in both inner and outer divertors as well as end-on plasma guns are electrically biased independently. As a result of effective outer-divertor electrode biasing alone, FRC plasma diamagnetism duration has reached up to ~9 ms which is equivalent to C-2U plasma duration. Magnetic field flaring/expansion in both inner and outer divertors plays an important role in creating a thermal insulation on open field-lines to reduce a loss rate of electrons, which leads to improvement of the edge and core FRC confinement properties. Experimental campaign with inner-divertor magnetic-field flaring has just commenced and early result indicates that electron temperature of the merged FRC stays relatively high and increases for a short period of time, presumably by NBI and ExB heating.

Published

2019

7. Development of a magnetized coaxial plasma gun for compact toroid injection into the C-2 field-reversed configuration device

Author

I. Allfrey, Tomohiko Asai, W. Waggoner, Thomas Roche, Michl Binderbauer, T. Valentine, M. Cordero, T. Tajima, M. Morehouse, S. Aefsky, Junichi Sekiguchi, T. Matsumoto, Hiroshi Gota, E. Garate, and J. S. Kinley

Subjects

Physics, Dense plasma focus, Reversed field pinch, Plasma parameters, Compact toroid, Plasma, 01 natural sciences, 010305 fluids & plasmas, 0103 physical sciences, Field-reversed configuration, Electron temperature, Coaxial, Atomic physics, 010306 general physics, Instrumentation

Abstract

A compact toroid (CT) injector was developed for the C-2 device, primarily for refueling of field-reversed configurations. The CTs are formed by a magnetized coaxial plasma gun (MCPG), which consists of coaxial cylindrical electrodes and a bias coil for creating a magnetic field. First, a plasma ring is generated by a discharge between the electrodes and is accelerated by Lorenz self-force. Then, the plasma ring is captured by an interlinkage flux (poloidal flux). Finally, the fully formed CT is ejected from the MCPG. The MCPG described herein has two gas injection ports that are arranged tangentially on the outer electrode. A tungsten-coated inner electrode has a head which can be replaced with a longer one to extend the length of the acceleration region for the CT. The developed MCPG has achieved supersonic CT velocities of ∼100 km/s. Plasma parameters for electron density, electron temperature, and the number of particles are ∼5 × 10(21) m(-3), ∼40 eV, and 0.5-1.0 × 10(19), respectively.

Published

2016

8. Recent breakthroughs on C-2U: Norman's legacy

Author

W. Waggoner, Thomas Roche, T. Tajima, Sean Dettrick, Y. Song, Laura Galeotti, Deepak Gupta, Ales Necas, A. H. Cheung, A. A. Ivanov, N. Bolte, M. Tuszewski, A. Sibley, M. Hollins, Erik Granstedt, Saurabh Gupta, Ryan Clary, K. Zhai, Sergey Korepanov, Erik Trask, R. Andow, Artem Smirnov, Xiaokang Yang, Richard Magee, Peter Yushmanov, L. Sevier, Marco Onofri, J. S. Kinley, D. Q. Bui, L. C. Steinhauer, Sergei Putvinski, F. Ceccherini, A. Van Drie, E. Garate, Bihe Deng, P. Feng, Y. Mok, J. H. Schroeder, K. Knapp, Francesco Giammanco, S. Primavera, K. D. Conroy, R. Mendoza, J. Romero, Nikolaus Rath, D. Osin, L. W. Schmitz, Daniel C. Barnes, M. C. Thompson, Jon Douglass, J. K. Walters, M. Binderbauer, and Hiroshi Gota

Subjects

Engineering, education.field_of_study, Physics and Astronomy (all), business.industry, Population, Electrical engineering, Plasma, Total pressure, business, education, Engineering physics, Magnetic flux, Beam (structure)

Abstract

Conventional field-reversed configurations (FRC) face notable stability and confinement concerns, which can be ameliorated by introducing and maintaining a significant fast ion population in the system. This is the conjecture first introduced by Norman Rostoker multiple decades ago and adopted as the central design tenet in Tri Alpha Energy’s advanced beam driven FRC concept. In fact, studying the physics of such neutral beam (NB) driven FRCs over the past decade, considerable improvements were made in confinement and stability. Next to NB injection, the addition of axially streaming plasma guns, magnetic end plugs, as well as advanced surface conditioning lead to dramatic reductions in turbulence driven losses and greatly improved stability. In turn, fast ion confinement improved significantly and allowed for the build-up of a dominant fast particle population. This recently led to the breakthrough of sustaining an advanced beam driven FRC, thereby demonstrating successful maintenance of trapped magnetic flux, plasma dimensions and total pressure inventory for times much longer than all characteristic system time scales and only limited by hardware and electric supply constraints.

Published

2016

9. A high performance field-reversed configurationa)

Author

L. W. Schmitz, A. Sibley, S. Primavera, Jon Douglass, M. C. Thompson, Sangeeta Gupta, Sergey Korepanov, T. Tajima, A. Van Drie, R. Mendoza, A. A. Ivanov, N. Bolte, R. M. Magee, Y. Song, J. Romero, Nikolaus Rath, K. Knapp, E. Granstedt, Peter Yushmanov, M. Tuszewski, K. D. Conroy, Deepak Gupta, Norman Rostoker, L. C. Steinhauer, J. H. Schroeder, Ales Necas, S. Aefsky, E. Garate, A. H. Cheung, Michl Binderbauer, R. Clary, Laura Galeotti, L. Sevier, K. Zhai, Marco Onofri, H. Y. Guo, Erik Trask, J. S. Kinley, M. Hollins, D. Osin, Dan Barnes, Bihe Deng, J. K. Walters, Tae Team, P. Feng, F. Ceccherini, Francesco Giammanco, Y. Mok, Hiroshi Gota, D. Q. Bui, W. Waggoner, Thomas Roche, Sean Dettrick, S. Putvinski, R. Andow, Xiaokang Yang, and Artem Smirnov

Subjects

Physics, education.field_of_study, Reversed field pinch, Population, Context (language use), Plasma, Fusion power, Condensed Matter Physics, Engineering physics, Neutral beam injection, Magnetic field, Physics::Plasma Physics, Electron temperature, Atomic physics, education

Abstract

Conventional field-reversed configurations (FRCs), high-beta, prolate compact toroids embedded in poloidal magnetic fields, face notable stability and confinement concerns. These can be ameliorated by various control techniques, such as introducing a significant fast ion population. Indeed, adding neutral beam injection into the FRC over the past half-decade has contributed to striking improvements in confinement and stability. Further, the addition of electrically biased plasma guns at the ends, magnetic end plugs, and advanced surface conditioning led to dramatic reductions in turbulence-driven losses and greatly improved stability. Together, these enabled the build-up of a well-confined and dominant fast-ion population. Under such conditions, highly reproducible, macroscopically stable hot FRCs (with total plasma temperature of ∼1 keV) with record lifetimes were achieved. These accomplishments point to the prospect of advanced, beam-driven FRCs as an intriguing path toward fusion reactors. This paper reviews key results and presents context for further interpretation.

Published

2015