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101. Laboratory observation and modeling of extreme ultraviolet spectra of highly ionized calcium

Author: K. B. Fournier, Vlad Soukhanovskii, H. W. Moos, D. Pacella, Michael Finkenthal, William H. Goldstein, S. Lippmann, G. Mazzitelli, and M. J. May
Subjects: Physics, Spectrometer, Physics::Plasma Physics, Extreme ultraviolet, Ab initio, General Physics and Astronomy, Electron temperature, Plasma, Atomic physics, Spectral line, Ion, Line (formation)
Abstract: Benchmarking and validation of atomic calcula- tions are crucial for understanding the properties of astro- physical and fusion plasmas. An extended re-evaluation of a previous experimental study of the Ca XVIII {C aXII extreme ultraviolet (XUV) spectra is presented. CaF2 was introduced into tokamak plasmas and the spectra of the calcium ions were recorded by a photometrically cali- brated grazing incidence time-resolved spectrometer. The local plasma electron temperature and density were mea- sured independently. Nearly all features of the line-of-sight integrated spectra were identied. Atomic data for this work were generated ab initio with the HULLAC suite of codes. The results of collisional-radiative (CR) modeling for individual charge states agree with the measured spec- tral line intensities within the experimental accuracy for most lines, thus validating the electron temperature and density diagnostic potential of the L-shell lines. In addi- tion, we compare experimentally measured and calculated line intensities with those calculated using the CHIANTI database.
Published: 2000

102. Benchmarking atomic physics models for magnetically confined fusion plasma physics experiments

Author: Vlad Soukhanovskii, William H. Goldstein, D. Pacella, H. W. Moos, Dan Stutman, Michael Finkenthal, K. B. Fournier, G. Mazzitelli, B. C. Gregory, and Mark May
Subjects: Physics, Tokamak, Radiative cooling, Divertor, Bremsstrahlung, Magnetic confinement fusion, law.invention, Physics::Plasma Physics, law, Ionization, Radiative transfer, Plasma diagnostics, Atomic physics, Instrumentation
Abstract: In present magnetically confined fusion devices, high and intermediate Z impurities are either puffed into the plasma for divertor radiative cooling experiments or are sputtered from the high Zplasma facing armor. The beneficial cooling of the edge as well as the detrimental radiative losses from the core of these impurities can be properly understood only if the atomic physics used in the modeling of the cooling curves is very accurate. To this end, a comprehensive experimental and theoretical analysis of some relevant impurities is undertaken. Gases (Ne, Ar, Kr, and Xe) are puffed and nongases are introduced through laser ablation into the FTU tokamak plasma. The charge state distributions and total density of these impurities are determined from spatial scans of several photometrically calibrated vacuum ultraviolet and x-ray spectrographs (3–1600 A), the multiple ionization state transport code transport code (MIST) and a collisional radiative model. The radiative power losses are measured with bolometery, and the emissivity profiles were measured by a visible bremsstrahlung array. The ionization balance, excitation physics, and the radiative cooling curves are computed from the Hebrew University Lawrence Livermore atomic code (HULLAC) and are benchmarked by these experiments. (Supported by U.S. DOE Grant No. DE-FG02-86ER53214 at JHU and Contract No. W-7405-ENG-48 at LLNL.)
Published: 1999

103. Spectroscopic evidence for high harmonic fast wave heating in the CDX-U spherical torus

Author: Michael Finkenthal, Robert Kaita, Vlad Soukhanovskii, Richard Majeski, Tobin Munsat, Jonathan Menard, and Dan Stutman
Subjects: Physics, Tokamak, Torus, Plasma, Condensed Matter Physics, Instability, law.invention, Nuclear Energy and Engineering, Core electron, law, Harmonics, Harmonic, Electron temperature, Atomic physics
Abstract: We present evidence for high harmonic fast wave (HHFW) heating in the core of the CDX-U spherical torus (aspect ratio R/a1.5) at the Princeton Plasma Physics Laboratory. We use a spectroscopic technique combining fast, multichordal measurements of the ultrasoft x-ray line emission from intrinsic C and O. The results show that in a few cases substantial (nearly 50%) increases in the core electron temperature can be obtained with only about 100 kW of radio-frequency power, compared to 150 kW ohmic input. Modifications of the core magnetohydrodynamic activity consistent with the estimated Te increase are also observed. The majority of the discharges exhibit only modest core Te increases however, with most of the heating occurring outside r/a0.5. A proposed explanation for this effect consistent with the experimental observations is based on a neoclassical transport instability for low-Z impurities, similar to an effect recently described for high-Z impurities in large tokamaks.
Published: 1999

104. Solenoid-free Plasma Start-up in NSTX using Transient CHI

Author: Brian Nelson, Lane Roquemore, Jonathan Menard, B.P. LeBlanc, Thomas Jarboe, R.J. Maqueda, Vlad Soukhanovskii, Masayoshi Nagata, M.G. Bell, Roger Raman, D. Mueller, and Masayuki Ono
Subjects: Physics, Nuclear and High Energy Physics, Tokamak, Toroid, Nuclear engineering, Torus, Solenoid, Plasma, Fusion power, law.invention, Nuclear physics, Nuclear Energy and Engineering, Physics::Plasma Physics, law, Electron temperature, Nuclear fusion
Abstract: Experiments in NSTX have now unambiguously demonstrated the coupling of toroidal plasmas produced by the technique of CHI to inductive sustainment and ramp-up of the toroidal plasma current. This is an important step because an alternate method for plasma startup is essential for developing a fusion reactor based on the spherical torus concept. Elimination of the central solenoid would also allow greater flexibility in the choice of the aspect ratio in tokamak designs now being considered. The transient CHI method for spherical torus startup was originally developed on the HIT-II experiment at the University of Washington.
Published: 2008

105. Impurity transport measurements of biased H mode in hydrogen and deuterium plasmas on the Phaedrus-T tokamak

Author: Vlad Soukhanovskii, E. Y. Wang, M. J. May, M. Doczy, S. P. Regan, N. Hershkowitz, Michael Finkenthal, Xin A Wang, H. W. Moos, and D. A. Diebold
Subjects: Nuclear and High Energy Physics, Tokamak, Materials science, Hydrogen, chemistry.chemical_element, Plasma, Condensed Matter Physics, law.invention, High-confinement mode, Deuterium, chemistry, Physics::Plasma Physics, law, Impurity, Ionization, Physics::Space Physics, Atomic physics, Spectroscopy
Abstract: Soft X-ray spectroscopy was used to study the transport of the dominating impurity, carbon, in the central region of the Phaedrus-T tokamak in ohmic and high confinement mode (H mode) plasmas. These H modes were induced by an electrode positioned in the edge of the plasma and biased positive with respect to the limiter. The primary source of carbon in the Phaedrus-T tokamak plasma is the graphite limiter. A soft X-ray polychromator utilizing multilayer mirrors (MLM) as dispersive elements simultaneously monitored the Lyman alpha emission of H-I-like carbon at 33.7 AA, and the blended singlet and triplet transitions of He-I-like carbon at 40.3 and 40.7 AA, respectively, and spatially resolved their distributions in the plasma with a temporal resolution of 1 ms. The measured impurity emission profiles from the ohmic and H mode portions of hydrogen and deuterium plasmas were analysed with the Multiple Ionization State Transport (MIST) code in order to estimate the impurity transport in the plasma. Large increases in the impurity particle confinement time were observed as the plasma made the transition from ohmic to H mode, and the improvement in the impurity confinement was found to be greater in the deuterium plasmas. Comparisons were made between the emission profiles, which are used to probe the effects of the H mode deep inside the plasma, and the I-V characteristics of the biased electrode, which are used to monitor the edge of the plasma. The I-V characteristics of the biased electrode were found to have a direct impact on the carbon emission profiles
Published: 1997

106. An evaluation of multilayer mirrors for the soft x ray and extreme ultraviolet wavelength range that were irradiated with neutrons

Author: Mark May, Charles S. Tarrio, Vlad Soukhanovskii, Susan Regan, H. W. Moos, Richard N. Watts, F W. Clinard, M. Finkenthal, and E H. Farnum
Subjects: Physics, business.industry, Neutron radiation, Radiation, Neutron temperature, Optics, Neutron flux, Extreme ultraviolet, Optoelectronics, Spallation, Wafer, Neutron, business, Instrumentation
Abstract: The Plasma Spectroscopy Group at the Johns Hopkins University develops high photon throughput multilayer mirror (MLM) based soft x ray and extreme ultraviolet (XUV 10 A
Published: 1997

107. Line emission tomography for CDX-U using filtered diodes

Author: J.E. Menard, Y. S. Hwang, Mark May, Vlad Soukhanovskii, Michael Finkenthal, Dan Stutman, Sean Regan, H. W. Moos, M. Ono, and Wonho Choe
Subjects: Physics, Electron density, business.industry, Photodiode, law.invention, Optics, law, Extreme ultraviolet, Electron temperature, Plasma diagnostics, Emission spectrum, Atomic physics, Spectral resolution, business, Instrumentation, Diode
Abstract: Electron density and temperature in the CDX-U low aspect ratio tokamak are too low to allow observation of fast magnetohydrodynamic activity using soft x-ray continuum emission. However, spectroscopic measurements show that extreme ultraviolet (XUV) line emission of intrinsic impurities is bright enough to observe such activity. In addition, a fast monitoring system for local temperature changes in the plasma core is required for planned auxiliary heating experiments. We present a spectrally resolved tomographic system for fast imaging of O VI 2s–np, 2p–nd (n⩾3), C V 1s2–1s2p and C VI 1s–2p XUV transitions. Using this emission, we can study both core and edge MHD activity, while the C VI to C V intensity ratio can indicate local changes in electron temperature. To achieve maximal throughput together with the needed spectral resolution, we use arrays of surface barrier diodes filtered with bandpass elemental filters. Using M edge filters (Zr, Pd, and Ag), we achieve both good discrimination between the abo...
Published: 1997

108. Imaging of molybdenum erosion and thermography at visible wavelengths in Alcator C-Mod ICRH and LHCD discharges

Author: S.J. Wukitch, Christian Theiler, Bruce Lipschultz, A.N. James, Cornwall Lau, D.G. Whyte, D.R. Miller, Matthew Reinke, G.M. Wallace, Dan Brunner, Brian LaBombard, J.L. Terry, and Vlad Soukhanovskii
Subjects: Physics, business.industry, Divertor, Astrophysics::High Energy Astrophysical Phenomena, Cyclotron, Plasma, Condensed Matter Physics, law.invention, Wavelength, Optics, Nuclear Energy and Engineering, Alcator C-Mod, Heat flux, law, Physics::Plasma Physics, Limiter, Atomic physics, business, Ohmic contact
Abstract: We describe results from imaging observations of atomic line and continuum emission in the 550.6 nm region on Alcator C-Mod. Both the 550.6 nm neutral molybdenum emission and the adjacent 549 nm continuum emission are imaged separately to isolate line emission. A few complications of using imaging to infer erosion in this wavelength region are discussed including subtraction of continuum emission and determination of an appropriate S/XB coefficient. Diagnostics of surface erosion and thermography using these emissions are briefly reviewed, and used to study phenomenology during ohmic operation, ion cyclotron range of frequencies heating (ICRH), and lower hybrid current drive (LHCD). In addition to broadening of Mo I emission regions in the outer divertor and main limiter during ICRH compared to ohmic operation, mid-plane localized heating of the main limiter associated with fast-ion impact is observed which exceeds the divertor heat flux. During LHCD operation, several localized regions of increased brightness associated with hot spots are interpreted as heating due to localized density peaking, which re-iterates the importance of imaging continuum emission for subtraction. These sources of surface heating exacerbate plasma–material interactions at the device wall and may require additional mitigation if they cannot be avoided in future machines.
Published: 2013

109. NSTX tangential divertor camera

Author: A. L. Roquemore, Nobuhiro Nishino, Vlad Soukhanovskii, T. M. Biewer, David Johnson, and S. J. Zweben
Subjects: Physics, Optical fiber, business.industry, Turbulence, Divertor, Plasma, law.invention, Magnetic field, Filter (large eddy simulation), Optics, Physics::Plasma Physics, law, Plasma diagnostics, Image sensor, business, Instrumentation
Abstract: Strong magnetic field shear around the divertor x-point is numerically predicted to lead to strong spatial asymmetries in turbulence driven particle fluxes. To visualize the turbulence and associated impurity line emission near the lower x-point region, a new tangential observation port has been recently installed on NSTX. A reentrant sapphire window with a moveable in-vessel mirror images the divertor region from the center stack out to R∼80 cm and views the x-point for most plasma configurations. A coherent fiber optic bundle transmits the image through a remotely selected filter to a fast camera, for example, a 40 500 frames/s photron complementary metal-oxide-semiconductor camera. A gas puffer located in the lower inboard divertor will localize the turbulence in the region near the x-point. Edge fluid and turbulent codes UEDGE and BOUT will be used to interpret impurity and deuterium emission fluctuation measurements in the divertor.
Published: 2004

110. Fast neutral pressure gauges in NSTX

Author: R. Gernhardt, T. Provost, Thomas Jarboe, Vlad Soukhanovskii, H.W. Kugel, and Roger Raman
Subjects: Physics, Toroidal and poloidal, Divertor, Nuclear engineering, Atmospheric-pressure plasma, Fusion power, law.invention, Pressure measurement, Physics::Plasma Physics, law, Hot-filament ionization gauge, Vacuum chamber, Plasma diagnostics, Atomic physics, Instrumentation
Abstract: Successful operation in NSTX of two prototype fast-response micro ionization gauges during plasma operations has motivated us to install five gauges at different toroidal and poloidal locations to measure the edge neutral pressure and its dependence on the type of discharge (L-mode, H-mode, CHI) and the fueling method and location. The edge neutral pressure is also used as an input to the transport analysis codes TRANSP and DEGAS-2. The modified PDX-type Penning gauges are well suited for pressure measurements in the NSTX divertor where the toroidal field is relatively high. Behind the NSTX outer divertor plates where the field is lower, an unshielded fast ion gauge of a new design has been installed. This gauge was developed after laboratory testing of several different designs in a vacuum chamber with applied magnetic fields.
Published: 2004

111. Diagnostics for molybdenum and tungsten erosion and transport in NSTX-U

Author: Vlad Soukhanovskii, Filippo Scotti, and Michael E. Weller
Subjects: 010302 applied physics, Materials science, Divertor, Nuclear engineering, chemistry.chemical_element, Plasma, Tungsten, 01 natural sciences, 010305 fluids & plasmas, chemistry, Physics::Plasma Physics, Molybdenum, Impurity, Sputtering, Extreme ultraviolet, 0103 physical sciences, Lithium, Atomic physics, Instrumentation
Abstract: A comprehensive set of spectroscopic diagnostics is planned in the National Spherical Torus Experiment Upgrade to connect measurements of molybdenum and tungsten divertor sources to scrape-off layer (SOL) and core impurity transport, supporting the installation of high-Z plasma facing components which is scheduled to begin with a row of molybdenum tiles. Imaging with narrow-bandpass interference filters and high-resolution spectroscopy will be coupled to estimate divertor impurity influxes. Vacuum ultraviolet and extreme ultraviolet spectrometers will allow connecting high-Z sources to SOL transport and core impurity content. The high-Z diagnostics suite complements the existing measurements for low-Z impurities (carbon and lithium), critical for the characterization of sputtering of high-Z materials.
Published: 2016

112. Three new extreme ultraviolet spectrometers on NSTX-U for impurity monitoring

Author: Vlad Soukhanovskii, E. W. Magee, Peter Beiersdorfer, Filippo Scotti, and Michael E. Weller
Subjects: Physics, Spectrometer, business.industry, Extreme ultraviolet lithography, Laser, 01 natural sciences, Electromagnetic radiation, 010305 fluids & plasmas, law.invention, 010309 optics, Optics, law, Extreme ultraviolet, 0103 physical sciences, Measuring instrument, Plasma diagnostics, Spectroscopy, business, Instrumentation
Abstract: Three extreme ultraviolet (EUV) spectrometers have been mounted on the National Spherical Torus Experiment-Upgrade (NSTX-U). All three are flat-field grazing-incidence spectrometers and are dubbed X-ray and Extreme Ultraviolet Spectrometer (XEUS, 8-70 Å), Long-Wavelength Extreme Ultraviolet Spectrometer (LoWEUS, 190-440 Å), and Metal Monitor and Lithium Spectrometer Assembly (MonaLisa, 50-220 Å). XEUS and LoWEUS were previously implemented on NSTX to monitor impurities from low- to high-Z sources and to study impurity transport while MonaLisa is new and provides the system increased spectral coverage. The spectrometers will also be a critical diagnostic on the planned laser blow-off system for NSTX-U, which will be used for impurity edge and core ion transport studies, edge-transport code development, and benchmarking atomic physics codes.
Published: 2016

113. Full toroidal imaging of non-axisymmetric plasma material interaction in the National Spherical Torus Experiment divertor

Author: Filippo Scotti, Vlad Soukhanovskii, and A. L. Roquemore
Subjects: Physics, Toroid, Tokamak, Dense plasma focus, Divertor, Rotational symmetry, Plasma, Computational physics, law.invention, Physics::Plasma Physics, law, Plasma diagnostics, Point (geometry), Atomic physics, Instrumentation
Abstract: A pair of two dimensional fast cameras with a wide angle view (allowing a full radial and toroidal coverage of the lower divertor) was installed in the National Spherical Torus Experiment in order to monitor non-axisymmetric effects. A custom polar remapping procedure and an absolute photometric calibration enabled the easier visualization and quantitative analysis of non-axisymmetric plasma material interaction (e.g., strike point splitting due to application of 3D fields and effects of toroidally asymmetric plasma facing components).
Published: 2012

114. Continuous Improvement of H-Mode Discharge Performance with Progressively Increasing Lithium Coatings in the National Spherical Torus Experiment

Author: M.G. Bell, Vlad Soukhanovskii, Robert Kaita, Dennis Boyle, Rajesh Maingi, H.W. Kugel, C.H. Skinner, S.M. Kaye, T.H. Osborne, Michael Jaworski, T.K. Gray, B.P. LeBlanc, John Canik, S.A. Sabbagh, R.E. Bell, and D.K. Mansfield
Subjects: Range (particle radiation), Materials science, business.industry, Mode (statistics), Evaporation, General Physics and Astronomy, chemistry.chemical_element, Electron, Edge (geometry), Nominal size, Optics, chemistry, Lithium, Composite material, business, National Spherical Torus Experiment
Abstract: Lithium wall coatings have been shown to reduce recycling, improve energy confinement, and suppress edge localized modes in the National Spherical Torus Experiment. Here, we show that these effects depend continuously on the amount of predischarge lithium evaporation. We observed a nearly monotonic reduction in recycling, decrease in electron transport, and modification of the edge profiles and stability with increasing lithium. These correlations challenge basic expectations, given that even the smallest coatings exceeded that needed for a nominal thickness of the order of the implantation range.
Published: 2011

115. Overview of the physics and engineering design of NSTX upgrade

Author: T. Stevenson, R. Maingi, Egemen Kolemen, Vlad Soukhanovskii, E. Perry, Stanley Kaye, M. Ono, J. Caniky, K. Tresemer, M. Williams, Jonathan Menard, C.E. Kessel, J. Chrzanowski, L. Dudek, Peter Titus, M. Viola, C. Neumeyer, R. Raman, S.P. Gerhardt, M. Smith, S.A. Sabbagh, M. Denault, and R. Strykowsky
Subjects: Physics, Upgrade, Tokamak, law, Nuclear engineering, Divertor, Nuclear fusion, Magnetic confinement fusion, Plasma, Collisionality, Atomic physics, Spherical tokamak, law.invention
Abstract: The spherical tokamak (ST) is a leading candidate for a fusion nuclear science facility (FNSF) due to its compact size and modular configuration. The National Spherical Torus eXperiment (NSTX) is a MA-class ST facility in the U.S. actively developing the physics basis for an ST-based FNSF. In plasma transport research, ST experiments exhibit a strong (nearly inverse) scaling of normalized confinement with collisionality, and if this trend holds at low collisionality, high fusion neutron fluences could be achievable in very compact ST devices. A major motivation for the NSTX Upgrade (NSTX-U) is to span the next factor of 3–6 reduction in collisionality. To achieve this collisionality reduction with equilibrated profiles, NSTX-U will double the toroidal field, plasma current, and NBI heating power and increase the pulse length from 1–1.5s to 5s. In the area of stability and advanced scenarios, plasmas with higher aspect ratio and elongation, high β N , and broad current profiles approaching those of an ST-based FNSF have been produced in NSTX using active control of the plasma β and advanced resistive wall mode control. High non-inductive current fractions of 70% have been sustained for many current diffusion times, and the more tangential injection of the 2nd NBI of the Upgrade is projected to increase the NBI current drive by up to a factor of 2 and support 100% non-inductive operation. More tangential NBI injection is also projected to provide non-solenoidal current ramp-up (from I P = 0.4MA up to 0.8–1MA) as needed for an ST-based FNSF. In boundary physics, NSTX and higher-A tokamaks measure an inverse relationship between the scrape-off layer heat-flux width and plasma current that could unfavorably impact next-step devices. Recently, NSTX has successfully demonstrated very high flux expansion and substantial heat-flux reduction using a snowflake divertor configuration, and this type of divertor is incorporated in the NSTX-U design. The physics and engineering design supporting NSTX Upgrade are described.
Published: 2011

116. Experiments with Liquid Metal Walls: Status of the Lithium Tokamak Experiment

Author: Thomas Kozub, Leonid E. Zakharov, Kevin Tritz, Vlad Soukhanovskii, Rajesh Maingi, L. Berzak, Gregory W. Hammett, H.W. Kugel, T.K. Gray, Dennis Boyle, Erik Granstedt, M. Lucia, B.P. LeBlanc, Richard Majeski, Trevor Strickler, S. Gershman, Robert Kaita, Jeffrey Spaleta, Andrew Jones, C.M. Jacobson, Nicholas Logan, Jonathan Menard, D.K. Mansfield, D.P. Lundberg, J. Timberlake, and Jongsoo Yoo
Subjects: Liquid metal, Tokamak, Materials science, Mechanical Engineering, Nuclear engineering, chemistry.chemical_element, Magnetic confinement fusion, Plasma, Fusion power, law.invention, Nuclear physics, Nuclear Energy and Engineering, chemistry, law, Limiter, Lithium Tokamak Experiment, General Materials Science, Lithium, Civil and Structural Engineering
Abstract: Liquid metal walls have been proposed to address the first wall challenge for fusion reactors. The Lithium Tokamak Experiment (LTX) at the Princeton Plasma Physics Laboratory (PPPL) is the first magnetic confinement device to have liquid metal plasma-facing components (PFC's) that encloses virtually the entire plasma. In the Current Drive Experiment-Upgrade (CDX-U), a predecessor to LTX at PPPL, the highest improvement in energy confinement ever observed in Ohmically-heated tokamak plasmas was achieved with a toroidal liquid lithium limiter. The LTX extends this liquid lithium PFC by using a conducting conformal shell that almost completely surrounds the plasma. By heating the shell, a lithium coating on the plasma-facing side can be kept liquefied. A consequence of the low-recycling conditions from liquid lithium walls is the need for efficient plasma fueling. For this purpose, a molecular cluster injector is being developed. Future plans include the installation of a neutral beam for core plasma fueling, and also ion temperature measurements using charge-exchange recombination spectroscopy. Low edge recycling is also predicted to reduce temperature gradients that drive drift wave turbulence. Gyrokinetic simulations are in progress to calculate fluctuation levels and transport for LTX plasmas, and new fluctuation diagnostics are under development to test these predictions. __________________________________________________
Published: 2010

117. Demonstration of Tokamak Ohmic Flux Saving by Transient Coaxial Helicity Injection on NSTX

Author: R. Raman, S. Sabbagh, M. Ono, H. W. Kugel, Vlad Soukhanovskii, Stefan Gerhardt, B. A. Nelson, S. Paul, B. Leblanc, T. R. Jarboe, L. Roquemore, D. Mueller, J.E. Menard, and R. Maingi
Subjects: Physics, Tokamak, Nuclear magnetic resonance, Current generation, law, Flux, Transient (oscillation), Coaxial, Electric current, Atomic physics, Ohmic contact, Helicity, law.invention
Abstract: Transient Coaxial Helicity Injection (CHI) started discharges in NSTX have attained peak currents up to 300 kA and when these discharges are coupled to induction, it has produced up to 200 kA additional current over inductive-only operation. CHI in NSTX has shown to be energetically quite efficient, producing a plasma current of about 10 A/Joule of capacitor bank energy. In addition, for the first time, the CHI produced toroidal current that couples to induction continues to increase with the energy supplied by the CHI power supply at otherwise similar values of the injector flux, indicating the potential for substantial current generation capability by CHI in NSTX and in future toroidal devices. __________________________________________________
Published: 2010

118. Demonstration of Tokamak Ohmic Flux Saving by Transient Coaxial Helicity Injection in the National Spherical Torus Experiment

Author: Roger Raman, Rajesh Maingi, S.F. Paul, Lane Roquemore, Vlad Soukhanovskii, H.W. Kugel, B. A. Nelson, D. Mueller, Thomas Jarboe, M. Ono, Jonathan Menard, S.A. Sabbagh, S.P. Gerhardt, and B.P. LeBlanc
Subjects: Physics, Toroid, Tokamak, General Physics and Astronomy, Plasma, Power factor, Helicity, Computational physics, law.invention, Nuclear magnetic resonance, Physics::Plasma Physics, law, Transient (oscillation), Electric current, Coaxial
Abstract: Transient coaxial helicity injection (CHI) started discharges in the National Spherical Torus Experiment (NSTX) have attained peak currents up to 300 kA and when coupled to induction, it has produced up to 200 kA additional current over inductive-only operation. CHI in NSTX has shown to be energetically quite efficient, producing a plasma current of about 10 A/J of capacitor bank energy. In addition, for the first time, the CHI-produced toroidal current that couples to induction continues to increase with the energy supplied by the CHI power supply at otherwise similar values of the injector flux, indicating the potential for substantial current generation capability by CHI in NSTX and in future toroidal devices.
Published: 2010

119. Near infrared plasma spectroscopy in support of divertor Thomson scattering diagnostics development for ITER

Author: E.E. Mukhin, Vlad Soukhanovskii, A Meigs, Nstx Team, M Beurskens, Valery S. Lisitsa, S Yu Tolstyakov, Aleksandra V. Zabuga, M.M. Kochergin, Vladimir V. Semenov, Philip Andrew, G. S. Kurskiev, Jet team, K. A. Podushnikova, M. G. Levashova, Globus-M team, S. Brezinsek, and A.G. Razdobarin
Subjects: Physics, History, Laser scattering, Magnetic fusion, Plasma spectroscopy, Thomson scattering, Continuum radiation, Divertor, Near-infrared spectroscopy, Computer Science Applications, Education, Nuclear physics, Physics::Plasma Physics, ddc:530, Line (formation)
Abstract: One of the main challenges of the implementation of divertor Thomson scattering system on ITER is weak laser scattering signal to be detected against intense background plasma radiation. The paper review briefly the line and continuum radiation data from present magnetic fusion devices in the spectral range of interest to TS diagnostics. The results will form the basis of design and development of the TS diagnostics for the ITER divertor.
Published: 2010

120. Performance projections for the lithium tokamak experiment (LTX)

Author: Richard Majeski, T. Strickler, L. Berzak, Jongsoo Yoo, Vlad Soukhanovskii, Fred Levinton, G. V. Pereverzev, J. Manickam, T. A. Kozub, T.K. Gray, Leonid E. Zakharov, D.P. Stotler, J. Spaleta, J. Timberlake, D.P. Lundberg, Robert Kaita, and K. Snieckus
Subjects: Nuclear and High Energy Physics, Materials science, Tokamak, chemistry.chemical_element, Electron, Condensed Matter Physics, Neutral beam injection, law.invention, chemistry, law, Limiter, Lithium Tokamak Experiment, Lithium, Atomic physics, Diffusion (business), Ohmic contact
Abstract: Use of a large-area liquid lithium limiter in the CDX-U tokamak produced the largest relative increase (an enhancement factor of 5–10) in Ohmic tokamak confinement ever observed. The confinement results from CDX-U do not agree with existing scaling laws, and cannot easily be projected to the new lithium tokamak experiment (LTX). Numerical simulations of CDX-U low recycling discharges have now been performed with the ASTRA-ESC code with a special reference transport model suitable for a diffusion-based confinement regime, incorporating boundary conditions for nonrecycling walls, with fuelling via edge gas puffing. This model has been successful at reproducing the experimental values of the energy confinement (4–6 ms), loop voltage (
Published: 2009

121. REVIEW OF THE NATIONAL SPHERICAL TORUS EXPERIMENT RESEARCH RESULTS

Author: Vlad Soukhanovskii, D.A. Gates, R.J. Maqueda, C.E. Bush, J.R. Ferron, Richard Majeski, S.A. Sabbagh, Dennis Mueller, J.A. Boedo, S.F. Paul, J.M. Bialek, Neville C. Luhmann, Fred Levinton, D.K. Mansfield, David R. Smith, W. Zhu, E.D. Fredrickson, M. G. Bell, Aaron Sontag, R. Maingi, S. J. Diem, S. Kubota, Calvin Domier, C.E. Kessel, E. Mazzucato, K. C. Lee, J. C. Hosea, James R. Wilson, B. C. Stratton, B.P. LeBlanc, W. A. Peebles, S.M. Kaye, H.K. Park, D.A. D'Ippolito, K. Tritz, J.E. Menard, Howard Yuh, J.R. Myra, C.H. Skinner, R.E. Bell, Stewart Zweben, Dan Stutman, H.W. Kugel, Roger Raman, S. S. Medley, G. Taylor, K. W. Hill, and Neal Crocker
Subjects: Nuclear physics, Physics, Toroid, Physics::Plasma Physics, Turbulence, Plasma, Electron, Electric current, Aspect ratio (image), Scaling, Neutral beam injection
Abstract: The National Spherical Torus Experiment (NSTX) produces plasmas, with toroidal aspect ratio as low as 1.25 and plasma currents up to 1.5 MA, which can be heated by up to 6 MW High‐Harmonic Fast Waves and up to 7 MW of deuterium Neutral Beam Injection. With these capabilities, NSTX has already made considerable progress in advancing the scientific understanding of high performance plasmas needed for low‐aspect‐ratio reactor concepts and for ITER. In transport and turbulence research on NSTX, the role of magnetic shear is being elucidated in discharges in which electron energy transport barriers are observed. Scaling studies indicate a weaker dependence on plasma current than at conventional aspect ratio and a significant dependence on toroidal field (BT).
Published: 2009

122. High Pressure Supersonic Gas Jet Fueling on NSTX

Author: Vlad Soukhanovskii, M.G. Bell, Robert Kaita, A. L. Roquemore, P. Sichta, W. Blanchard, J. K. Dong, H.W. Kugel, T. Provost, and R. Gernhardt
Subjects: Materials science, Nuclear engineering, Nozzle, Plasma, Injector, Plenum space, law.invention, symbols.namesake, Mach number, law, Torr, symbols, Supersonic speed, Atomic physics, Choked flow
Abstract: A supersonic gas injector (SGI) has been developed for fueling and diagnostic applications on NSTX. The SGI is comprised of a small de Laval converging-diverging graphite nozzle, a commercial piezoelectric gas valve, and a diagnostic package, all mounted on a movable probe at a low field side midplane port location. The nozzle operated in a pulsed regime at room temperature, reservoir deuterium pressure up to 2500 Torr (50 PSIA), flow rate up to 65 Torr 1 /s (4.55e2f particles/s), and a measured Mach number of about 4. In initial experiments the SGI was used for fueling of ohmic and 2 -6 MW NBI-heated L-and H-mode plasmas. Reliable H-mode access was obtained with SGI fueling, with a fueling efficiency in the range 0.1 -0.3. Good progress was also made toward a controlled density SGI-fueled H-mode plasma scenario with the flow rate of the uncontrolled high field side (HFS) gas injector reduced by up to 20. These experiments motivated a number of SGI upgrades: 1) the maximum plenum pressure has been increased to 5000 Torr (100 PSIA), 2) the plenum pressure volume has been doubled, 3) the gas delivery system has been changed to allow for injection of various gases, 4) a multi-pulse capability has been implemented. As a result of the upgrades, the maximum flow rate increased to about 130 Torr 1 /s. Laboratory gas jet characterization tests indicated a Mach number of about 4 with H2 and I) , and 4-6 with He and N2. Plasma experiments demonstrated the high-pressure gas jet fueling compatibility with H-mode plasmas, high fueling efficiency (0.1 -0.3), and high SOL penetration.
Published: 2007

123. The snowflake divertor

Author: Vlad Soukhanovskii and D. D. Ryutov
Subjects: Physics, Tokamak, Divertor, Plasma, Condensed Matter Physics, Null (physics), Action (physics), Computational physics, Magnetic field, law.invention, Heat flux, law, Snowflake, Atomic physics
Abstract: The snowflake magnetic configuration is characterized by the presence of two closely spaced poloidal field nulls that create a characteristic hexagonal (reminiscent of a snowflake) separatrix structure. The magnetic field properties and the plasma behaviour in the snowflake are determined by the simultaneous action of both nulls, this generating a lot of interesting physics, as well as providing a chance for improving divertor performance. Among potential beneficial effects of this geometry are: increased volume of a low poloidal field around the null, increased connection length, and the heat flux sharing between multiple divertor channels. The authors summarise experimental results obtained with the snowflake configuration on several tokamaks. Wherever possible, relation to the existing theoretical models is described.
Published: 2015

124. Progress toward commissioning and plasma operation in NSTX-U

Author: M. Williams, M. Cropper, S.P. Gerhardt, Ahmed Diallo, M. Smith, Vlad Soukhanovskii, J. Hosea, A. von Halle, T. Stevenson, A. L. Roquemore, G. Taylor, Robert Kaita, R. Hatcher, R. Strykowsky, Keith Erickson, P.J. Heitzenroeder, G. Labik, M. Ono, S.M. Kaye, E. Perry, K. Tresemer, L. Dudek, P. Sichta, S. Jurczynski, A. Zolfaghari, Roger Raman, B.P. LeBlanc, J. Lawson, J. Chrzanowski, Robert Ellis, C. Neumeyer, S.A. Sabbagh, N.D. Atnafu, David Gates, R. Maingi, Peter Titus, H. Schneider, W. Blanchard, Jonathan Menard, B. Stratton, S. Raftopoulos, and R. Ramakrishnan
Subjects: Physics, Nuclear and High Energy Physics, Upgrade, Toroid, Power station, Neutron flux, Nuclear engineering, Nuclear fusion, Plasma, Collisionality, Condensed Matter Physics, Neutral beam injection
Abstract: The National Spherical Torus Experiment-Upgrade (NSTX-U) is the most powerful spherical torus facility at PPPL, Princeton USA. The major mission of NSTX-U is to develop the physics basis for an ST-based Fusion Nuclear Science Facility (FNSF). The ST-based FNSF has the promise of achieving the high neutron fluence needed for reactor component testing with relatively modest tritium consumption. At the same time, the unique operating regimes of NSTX-U can contribute to several important issues in the physics of burning plasmas to optimize the performance of ITER. NSTX-U further aims to determine the attractiveness of the compact ST for addressing key research needs on the path toward a fusion demonstration power plant (DEMO). The upgrade will nearly double the toroidal magnetic field BT to 1 T at a major radius of R0 = 0.93 m, plasma current Ip to 2 MA and neutral beam injection (NBI) heating power to 14 MW. The anticipated plasma performance enhancement is a quadrupling of the plasma stored energy and near doubling of the plasma confinement time, which would result in a 5–10 fold increase in the fusion performance parameter nτ T. A much more tangential 2nd NBI system, with 2–3 times higher current drive efficiency compared to the 1st NBI system, is installed to attain the 100% non-inductive operation needed for a compact FNSF design. With higher fields and heating powers, the NSTX-U plasma collisionality will be reduced by a factor of 3–6 to help explore the favourable trend in transport towards the low collisionality FNSF regime. The NSTX-U first plasma is planned for the Summer of 2015, at which time the transition to plasma operations will occur.
Published: 2015

125. Enhanced energy confinement and performance in a low-recycling tokamak

Author: J. Spaleta, R.P. Doerner, Robert Kaita, D.K. Mansfield, Vlad Soukhanovskii, J. Timberlake, T.K. Gray, R. Maingi, Leonid E. Zakharov, and Richard Majeski
Subjects: Physics, Tokamak, Hydrogen, General Physics and Astronomy, chemistry.chemical_element, Plasma, law.invention, chemistry, law, Lithium Tokamak Experiment, Lithium, Atomic physics, Liquid lithium, Ohmic contact, Energy (signal processing)
Abstract: Extensive lithium wall coatings and liquid lithium plasma-limiting surfaces reduce recycling, with dramatic improvements in Ohmic plasma discharges in the Current Drive Experiment-Upgrade. Global energy confinement times increase by up to 6 times. These results exceed confinement scalings such as $\mathrm{ITER}98\mathrm{P}(y,1)$ by $2--3$ times, and represent the largest increase in energy confinement ever observed for an Ohmic tokamak plasma. Measurements of ${D}_{\ensuremath{\alpha}}$ emission indicate that global recycling coefficients decrease to approximately 0.3, the lowest documented for a magnetically confined hydrogen plasma.
Published: 2006

126. Supersonic gas injector for plasma fueling

Author: Vlad Soukhanovskii, H.W. Kugel, Richard Majeski, R. Kaita, P. Sichta, T. Provost, W. R. Blanchard, Roger Raman, A. L. Roquemore, R. Gernhardt, J.E. Menard, T.K. Gray, G. Gettelfinger, M. G. Bell, and C.E. Bush
Subjects: Jet (fluid), Materials science, Toroid, business.industry, Nozzle, Injector, Plasma, law.invention, symbols.namesake, Optics, Mach number, law, symbols, Langmuir probe, Supersonic speed, Atomic physics, business
Abstract: A supersonic gas injector (SGI) has been developed for fueling and diagnostic applications on the National Spherical Torus Experiment (NSTX). It is comprised of a graphite converging-diverging Laval nozzle and a commercial piezoelectric gas valve mounted on a movable probe at a low field side midplane port location. Also mounted on the probe is a diagnostic package: a Langmuir probe, two thermocouples and five pick-up coils for measuring toroidal, radial, vertical magnetic field components and magnetic fluctuations at the location of the SGI tip. The SGI flow rate is up to 4times1021 particles/s, comparable to conventional NSTX gas injectors. The nozzle operates in a pulsed regime at room temperature and a reservoir gas pressure up to 0.33 MPa. The deuterium jet Mach number of about 4, and the divergence half-angle of 5deg - 25deg have been measured in laboratory experiments simulating NSTX environment. In initial NSTX experiments reliable operation of the SGI and all mounted diagnostics at distances 1-20 cm from the plasma separatrix has been demonstrated. The SGI has been used for fueling of ohmic and 2-4 MW NBI heated L- and H-mode plasmas. Fueling efficiency in the range 0.1-0.3 has been obtained from the plasma electron inventory analysis
Published: 2005

127. Liquid Lithium Limiter Experiments in CDX-U

Author: J. Timberlake, Leonid E. Zakharov, Michael Finkenthal, Vlad Soukhanovskii, R. Kaita, R. Seraydarian, D. Rodgers, R.P. Doerner, T.K. Gray, S. Jardin, P. Marfuta, R. Majeski, S. Luckhardt, J. Spaleta, Dan Stutman, R. Maingi, and G. Antar
Subjects: Liquid metal, Tokamak, Toroid, Analytical chemistry, chemistry.chemical_element, Plasma, law.invention, chemistry, law, Limiter, Electron temperature, Lithium, Atomic physics, Electric current
Abstract: Recent experiments in the Current Drive Experiment-Upgrade provide a first-ever test of large area liquid lithium surfaces as a tokamak first wall, to gain engineering experience with a liquid metal first wall, and to investigate whether very low recycling plasma regimes can be accessed with lithium walls. The CDX-U is a compact (R = 34 cm, a = 22 cm, B{sub toroidal} = 2 kG, I{sub P} = 100 kA, T{sub e}(0) = 100 eV, n{sub e}(0) {approx} 5 x 10{sup 19} m{sup -3}) spherical torus at the Princeton Plasma Physics Laboratory. A toroidal liquid lithium tray limiter with an area of 2000 cm{sup 2} (half the total plasma limiting surface) has been installed in CDX-U. Tokamak discharges which used the liquid lithium limiter required a fourfold lower loop voltage to sustain the plasma current, and a factor of 5-8 increase in gas fueling to achieve a comparable density, indicating that recycling is strongly reduced. Modeling of the discharges demonstrated that the lithium-limited discharges are consistent with Z{sub effective} < 1.2 (compared to 2.4 for the pre-lithium discharges), a broadened current channel, and a 25% increase in the core electron temperature. Spectroscopic measurements indicate that edge oxygen and carbon radiationmore » are strongly reduced.« less
Published: 2004

128. Accounting of the Power Balance for Neutral-beam-heated H-Mode Plasmas in NSTX

Author: Rajesh Maingi, Vlad Soukhanovskii, Stanley Kaye, S.F. Paul, and H.W. Kugel
Subjects: Physics, Range (particle radiation), Power Balance, Divertor, Plasma, Radiation, Atomic physics, Electric current, Beam (structure), Ion
Abstract: A survey of the dependence of power balance on input power, shape, and plasma current was conducted for neutral-beam-heated plasmas in the National Spherical Torus Experiment (NSTX). Measurements of heat to the divertor strike plates and divertor and core radiation were taken over a wide range of plasma conditions. The different conditions were obtained by inducing a L-mode to H-mode transition, changing the divertor configuration [lower single null (LSN) vs. double-null (DND)] and conducting a NBI power scan in H-mode. 60-70% of the net input power is accounted for in the LSN discharges with 20% of power lost as fast ions, 30-45% incident on the divertor plates, up to 10% radiated in the core, and about 12% radiated in the divertor. In contrast, the power accountability in DND is 85-90%. A comparison of DND and LSN data show that the remaining power in the LSN is likely to be directed to the upper divertor
Published: 2004

129. Testing of Liquid Lithium Limiters in CDX-U

Author: Richard Majeski, R. Maingi, G. Antar, D. Hoffman, D. Rodgers, Vlad Soukhanovskii, R. Kaita, P. C. Efthimion, A. Post-Zwicker, Tobin Munsat, Leonid E. Zakharov, S. C. Luckhardt, M. Maiorano, J.E. Menard, G. Taylor, Sterling Smith, M. Boaz, J. Timberlake, J. Spaleta, Michael Finkenthal, R. Seraydarian, R.P. Doerner, Dan Stutman, B. Jones, H.W. Kugel, T.K. Gray, and R. Woolley
Subjects: Liquid metal, Tokamak, Materials science, Nuclear engineering, Divertor, Analytical chemistry, chemistry.chemical_element, Plasma, Spherical tokamak, law.invention, chemistry, law, Limiter, Lithium, Electric current
Abstract: Part of the development of liquid metals as a first wall or divertor for reactor applications must involve the investigation of plasma-liquid metal interactions in a functioning tokamak. Most of the interest in liquid-metal walls has focused on lithium. Experiments with lithium limiters have now been conducted in the Current Drive Experiment-Upgrade (CDX-U) device at the Princeton Plasma Physics Laboratory. Initial experiments used a liquid-lithium rail limiter (L3) built by the University of California at San Diego. Spectroscopic measurements showed some reduction of impurities in CDX-U plasmas with the L3, compared to discharges with a boron carbide limiter. While no reduction in recycling was observed with the L3, which had a plasma-wet area of approximately 40 cm2, subsequent experiments with a larger area fully toroidal lithium limiter demonstrated significant reductions in both recycling and in impurity levels. Two series of experiments with the toroidal limiter have now be en performed. In each series, the area of exposed, clean lithium was increased, until in the latest experiments the liquid-lithium plasma-facing area was increased to 2000 cm2. Under these conditions, the reduction in recycling required a factor of eight increase in gas fueling in order to maintain the plasma density. The loop voltage required to sustain the plasma current was reduced from 2 V to 0.5 V. This paper summarizes the technical preparations for lithium experiments and the conditioning required to prepare the lithium surface for plasma operations. The mechanical response of the liquid metal to induced currents, especially through contact with the plasma, is discussed. The effect of the lithium-filled toroidal limiter on plasma performance is also briefly described.
Published: 2004

130. NSTX Tangential Divertor Camera

Author: T. M. Biewer, Vlad Soukhanovskii, S. J. Zweben, Nobuhiro Nishino, David Johnson, and A. L. Roquemore
Subjects: Physics, Optical fiber, business.industry, Turbulence, Divertor, Plasma, Magnetic field, law.invention, Filter (large eddy simulation), Optics, Stack (abstract data type), Physics::Plasma Physics, law, business, Line (formation)
Abstract: Strong magnetic field shear around the divertor x-point is numerically predicted to lead to strong spatial asymmetries in turbulence driven particle fluxes. To visualize the turbulence and associated impurity line emission near the lower x-point region, a new tangential observation port has been recently installed on NSTX. A reentrant sapphire window with a moveable in-vessel mirror images the divertor region from the center stack out to R 80 cm and views the x-point for most plasma configurations. A coherent fiber optic bundle transmits the image through a remotely selected filter to a fast camera, for example a 40500 frames/sec Photron CCD camera. A gas puffer located in the lower inboard divertor will localize the turbulence in the region near the x-point. Edge fluid and turbulent codes UEDGE and BOUT will be used to interpret impurity and deuterium emission fluctuation measurements in the divertor.
Published: 2004

131. ELMs and the H-mode Pedestal in NSTX

Author: R. Raman, Vlad Soukhanovskii, Jose Boedo, Eric Fredrickson, Steven Sabbagh, Robert Kaita, M.G. Bell, Stanley Kaye, Rajesh Maingi, H.W. Kugel, D. Mueller, B.P. LeBlanc, T. Stevenson, Jonathan Menard, A. L. Roquemore, David Johnson, Kevin Tritz, Dan Stutman, C.E. Bush, David Gates, and R. E. Bell
Subjects: Physics, Pedestal, Phase (waves), Mode (statistics), Plasma, Electric current, Magnetohydrodynamics, Atomic physics, Scaling, Bootstrap current
Abstract: We report on the behavior of ELMs in NBI-heated H-mode plasmas in NSTX. It is observed that the size of Type I ELMs, characterized by the change in plasma energy, decreases with increasing density, as observed at conventional aspect ratio. It is also observed that the Type I ELM size decreases as the plasma equilibrium is shifted from a symmetric double-null toward a lower single-null configuration. Type III ELMs have also been observed in NSTX, as well as a high-performance regime with small ELMs which we designate Type V. These Type V ELMs are consistent with high bootstrap current operation and density approaching Greenwald scaling. The Type V ELMs are characterized by an intermittent n=1 MHD mode rotating counter to the plasma current. Without active pumping, the density rises continuously through the Type V phase. However, efficient in-vessel pumping should allow density control, based on particle containment time estimates.
Published: 2004

132. Effects of Large Area Liquid Lithium Limiters on Spherical Torus Plasmas

Author: G. Gettelfinger, P. C. Efthimion, G. Taylor, Vlad Soukhanovskii, R. Causey, B. Jones, D. Buchenauer, L. F. Delgado-Aparicio, G. Antar, Tobin Munsat, Stephen Jardin, D. Rodgers, P. Marfuta, R. P. Seraydarian, M.A. Ulrickson, M.J. Baldwin, Russ Doerner, S. C. Luckhardt, S. Raftopoulos, J. Spaleta, Rajesh Maingi, C. Neumeyer, Leonid E. Zakharov, M.M. Menon, R. Majeski, D. Hoffman, R. Kaita, T.K. Gray, R. Woolley, Michael Finkenthal, H.W. Kugel, M. Boaz, J. Timberlake, Dan Stutman, and Robert W. Conn
Subjects: Toroid, Chemistry, Impurity, Drop (liquid), Limiter, chemistry.chemical_element, Lithium, Plasma, Electric current, Atomic physics, Current (fluid)
Abstract: Use of a large-area liquid lithium surface as a first wall has significantly improved the plasma performance in the Current Drive Experiment-Upgrade (CDX-U) at the Princeton Plasma Physics Laboratory. Previous CDX-U experiments with a partially-covered toroidal lithium limiter tray have shown a decrease in impurities and the recycling of hydrogenic species. Improvements in loading techniques have permitted nearly full coverage of the tray surface with liquid lithium. Under these conditions, there was a large drop in the loop voltage needed to sustain the plasma current. The data are consistent with simulations that indicate more stable plasmas having broader current profiles, higher temperatures, and lowered impurities with liquid lithium walls. As further evidence for reduced recycling with a liquid lithium limiter, the gas puffing had to be increased by up to a factor of eight for the same plasma density achieved with an empty toroidal tray limiter.
Published: 2004

133. Observation of a High Performance Operating Regime with Small Edge-Localized Modes in the National Spherical Torus Experiment

Author: Rajesh Maingi, D. Mueller, A. L. Roquemore, Eric Fredrickson, Robert Kaita, Jonathan Menard, Vlad Soukhanovskii, H.W. Kugel, R. Raman, C.E. Bush, David Johnson, Stanley Kaye, Dan Stutman, Steven Sabbagh, Kevin Tritz, David Gates, M.G. Bell, R. E. Bell, and B.P. LeBlanc
Subjects: Physics, Fusion, Physics::Plasma Physics, Divertor, Stored energy, Perturbation (astronomy), Atomic physics, National Spherical Torus Experiment, Scaling, Computational physics, Bootstrap current
Abstract: We report observation of a high performance scenario in the National Spherical Torus Experiment with very small edge-localized modes (ELMs). These ELMs have no measurable impact on stored energy and are consistent with high bootstrap current operation with line average density approaching Greenwald scaling. The ELM perturbation is observed to typically originate near the lower divertor region, as opposed to the outer midplane for ELMs described in the literature. If extrapolable, this scenario would provide an attractive operating regime for next step fusion experiments
Published: 2004

134. Aspect Ratio Scaling of Ideal No-wall Stability Limits in High Bootstrap Fraction Tokamak Plasmas

Author: Vlad Soukhanovskii, S.A. Sabbagh, B.P. LeBlanc, M. G. Bell, R.E. Bell, S.M. Kaye, D.A. Gates, Dan Stutman, R. Maingi, and J.E. Menard
Subjects: Physics, Tokamak, Condensed matter physics, law, Plasma, Magnetohydrodynamic drive, Magnetohydrodynamics, Plasma stability, Scaling, Magnetic field, Computational physics, Bootstrap current, law.invention
Abstract: Recent experiments in the low aspect ratio National Spherical Torus Experiment (NSTX) [M. Ono et al., Nucl. Fusion 40 (2000) 557] have achieved normalized beta values twice the conventional tokamak limit at low internal inductance and with significant bootstrap current. These experimental results have motivated a computational re-examination of the plasma aspect ratio dependence of ideal no-wall magnetohydrodynamic stability limits. These calculations find that the profile-optimized no-wall stability limit in high bootstrap fraction regimes is well described by a nearly aspect ratio invariant normalized beta parameter utilizing the total magnetic field energy density inside the plasma. However, the scaling of normalized beta with internal inductance is found to be strongly aspect ratio dependent at sufficiently low aspect ratio. These calculations and detailed stability analyses of experimental equilibria indicate that the nonrotating plasma no-wall stability limit has been exceeded by as much as 30% in NSTX in a high bootstrap fraction regime.
Published: 2003

135. Progress Towards High Performance, Steady-state Spherical Torus

Author: Ezekial A Unterberg, Hantao Ji, L. Dudek, A. Rosenberg, J. Timberlake, Michael Finkenthal, R. E. Barry, J. Manickam, E. J. Synakowski, M. G. Bell, L. R. Grisham, C.E. Kessel, Dennis Mueller, J.A. Boedo, M.I. Williams, R.J. Hawryluk, Osamu Mitarai, S.M. Kaye, R. Marsala, Ryan J. Schooff, F. Paoletti, S. G. Lee, H.W. Kugel, R. Hatcher, G. Oliaro, G. D. Porter, J.E. Menard, K. Tritz, Ker-Chung Shaing, R. Parsells, Wonho Choe, S.F. Paul, Vlad Soukhanovskii, J. Foley, T. Gibney, J. Spaleta, T.K. Gray, P.T. Bonoli, C.H. Skinner, P. Sichta, Jayhyun Kim, T. N. Stevenson, R. W. Harvey, A. L. Roquemore, B. Peneflor, R.P. Doerner, D. Piglowski, P. C. Efthimion, M. Ono, M.J. Schaffer, Xian-Zhu Tang, P.M. Ryan, Kun-Chun Lee, Manfred Bitter, T.S. Bigelow, D.P. Stotler, S. S. Medley, R. Vero, Neville C. Luhmann, D.W. Swain, Masayoshi Nagata, Yuichi Takase, B. Blagojevic, R.E. Bell, J. L. Lowrance, R.I. Pinsker, S. Shiraiwa, G. Rewoldt, William Heidbrink, Nobuhiro Nishino, J.R. Ferron, C.E. Bush, Hyeon K. Park, C. Neumeyer, G. Taylor, K. W. Hill, C. K. Phillips, James R. Wilson, D.A. Gates, R. Seraydarian, R. J. Akers, Clarisse Bourdelle, E. Fredd, M.E. Rensink, D. Hoffman, P. Roney, L.L. Lao, William R. Wampler, Aaron Sontag, W. Davis, W. Park, Xueqiao Xu, Stewart Zweben, T. K. Mau, S.A. Sabbagh, Dan Stutman, Yueng Kay Martin Peng, Jan Egedal, Thomas Jarboe, Roger Raman, B.T. Lewicki, S. Kubota, R.J. Fonck, E.D. Fredrickson, Richard Majeski, M.M. Menon, Abhay K. Ram, J. C. Hosea, B. C. Stratton, C. N. Ostrander, D. S. Darrow, D. Mastravito, B.P. LeBlanc, Peter Beiersdorfer, Brian Nelson, Wayne A Houlberg, Mark Gilmore, G.D. Garstka, R. Maingi, Carter, B. H. Deng, J. Chrzanowski, G. A. Wurden, P. H. Probert, S. Ramakrishnan, S. C. Luckhardt, M. H. Redi, R.J. Maqueda, W. R. Blanchard, Richard Ellis, M. Kalish, S. J. Diem, J.M. Bialek, Fred Levinton, E. Mazzucato, A. H. Glasser, Stephen Jardin, Robert James Goldston, A. von Halle, R. Kaita, T. Peebles, John B Wilgen, Michael W Kissick, David W. Johnson, and D. Pacella
Subjects: Engineering, Toroid, Tokamak, business.industry, Nuclear engineering, Electrical engineering, Context (language use), Fusion power, Spherical tokamak, Bootstrap current, law.invention, law, Harmonics, Beta (plasma physics), business
Abstract: Research on the Spherical Torus (or Spherical Tokamak) is being pursued to explore the scientific benefits of modifying the field line structure from that in more moderate aspect-ratio devices, such as the conventional tokamak. The Spherical Tours (ST) experiments are being conducted in various U.S. research facilities including the MA-class National Spherical Torus Experiment (NSTX) at Princeton, and three medium-size ST research facilities: Pegasus at University of Wisconsin, HIT-II at University of Washington, and CDX-U at Princeton. In the context of the fusion energy development path being formulated in the U.S., an ST-based Component Test Facility (CTF) and, ultimately a Demo device, are being discussed. For these, it is essential to develop high-performance, steady-state operational scenarios. The relevant scientific issues are energy confinement, MHD stability at high beta (B), noninductive sustainment, ohmic-solenoid-free start-up, and power and particle handling. In the confinement area, the NSTX experiments have shown that the confinement can be up to 50% better than the ITER-98-pby2 H-mode scaling, consistent with the requirements for an ST-based CTF and Demo. In NSTX, CTF-relevant average toroidal beta values bT of up to 35% with the near unity central betaT have been obtained. NSTX will be exploring advanced regimes where bT up to 40% can be sustained through active stabilization of resistive wall modes. To date, the most successful technique for noninductive sustainment in NSTX is the high beta-poloidal regime, where discharges with a high noninductive fraction ({approx}60% bootstrap current + neutral-beam-injected current drive) were sustained over the resistive skin time. Research on radio-frequency-based heating and current drive utilizing HHFW (High Harmonic Fast Wave) and EBW (Electron Bernstein Wave) is also pursued on NSTX, Pegasus, and CDX-U. For noninductive start-up, the Coaxial Helicity Injection (CHI), developed in HIT/HIT-II, has been adopted on NSTX to test the method up to Ip {approx} 500 kA. In parallel, start-up using radio-frequency current drive and only external poloidal field coils are being developed on NSTX. The area of power and particle handling is expected to be challenging because of the higher power density expected in the ST relative to that in conventional aspect-ratio tokamaks. Due to its promise for power and particle handling, liquid lithium is being studied in CDX-U as a potential plasma-facing surface for a fusion reactor.
Published: 2003

136. Multilayer mirror based monitors for impurity controls in large fusion reactor type devices

Author: Michael Finkenthal, Vlad Soukhanovskii, M. J. May, S. P. Regan, and H. W. Moos
Subjects: Physics, Tokamak, business.industry, Divertor, Plasma, Fusion power, law.invention, Optics, law, Extreme ultraviolet, Neutron, Spallation, Plasma diagnostics, Atomic physics, business
Abstract: Multilayer mirror (MLM) based monitors are compact, high throughput diagnostics capable of extracting XUV emissions (the wavelength range including the soft-X-ray and the extreme ultraviolet, 10 /spl Aring/ to 304 /spl Aring/) of impurities from the harsh environment of large fusion reactor type devices. For several years the Plasma Spectroscopy Group at Johns Hopkins University has investigated the application of MLM based XUV spectroscopic diagnostics for magnetically confined fusion plasmas. MLM based monitors have been constructed for and extensively used on DIII-D, Alcator C-Mod, TEXT, Phaedrus-T, and CDX-U tokamaks to study the impurity behavior of elements ranging from He to Mo. On ITER MLM based devices would be used to monitor the spectral line emissions from Li I-like to F I-like charge states of Fe, Cr, and Ni, as well as 'extractors' for the bands of emissions from high Z elements such as Mo or W for impurity controls of the fusion plasma. In addition to monitoring the impurity emissions from the main plasma, MLM based devices can also be adapted for radiation measurements of low Z elements in the divertor. The concepts and designs of these MLM based monitors for impurity controls in ITER will be presented. The results of neutron irradiation experiments of the MLMs performed in the Los Alamos Spallation Radiation Effects Facility (LASREF) at the Los Alamos National Laboratory will also be discussed. These preliminary neutron exposure studies show that the dispersive and reflective qualities of the MLMs were not affected in a significant manner.
Published: 2002

137. Core Fueling and Edge Particle Flux Analysis in Ohmically and Auxiliary Heated NSTX Plasmas

Author: Roger Raman, Vlad Soukhanovskii, B.P. LeBlanc, Lane Roquemore, R. Maingi, C.H. Skinner, and H.W. Kugel
Subjects: Physics, Range (particle radiation), Physics::Plasma Physics, law, Divertor, Harmonics, Particle, Injector, Plasma, Atomic physics, Neutral beam injection, law.invention, Ion
Abstract: The Boundary Physics program of the National Spherical Torus Experiment (NSTX) is focusing on optimization of the edge power and particle flows in b * 25% L- and H-mode plasmas of t {approx} 0.8 s duration heated by up to 6 MW of high harmonic fast wave and up to 5 MW of neutral beam injection. Particle balance and core fueling efficiencies of low and high field side gas fueling of L-mode homic and NBI heated plasmas have been compared using an analytical zero dimensional particle balance model and measured ion and neutral fluxes. Gas fueling efficiencies are in the range of 0.05-0.20 and do not depend on discharge magnetic configuration, density or poloidal location of the injector. The particle balance modeling indicates that the addition of HFS fueling results in a reversal of the wall loading rate and higher wall inventories. Initial particle source estimates obtained from neutral pressure and spectroscopic measurements indicate that ion flux into the divertor greatly exceeds midplane ion flux from the main plasma, suggesting that the scrape-off cross-field transport plays a minor role in diverted plasmas. Present analysis provides the basis for detailed fluid modeling of core and edge particle flows and particle confinement properties of NSTX plasmas. This research was supported by the U.S. Department of Energy under contracts No. DE-AC02-76CH03073, DE-AC05-00OR22725, and W-7405-ENG-36.
Published: 2002

138. Operational Regimes of the National Spherical Torus Experiment

Author: Richard Majeski, S.M. Kaye, Vlad Soukhanovskii, Manfred Bitter, D.W. Swain, G. A. Wurden, Roger Raman, R.I. Pinsker, Mark D. Carter, C. K. Phillips, David W. Johnson, Masayuki Ono, J.R. Ferron, John B Wilgen, C.H. Skinner, Yuichi Takase, R.E. Bell, F. Paoletti, R. Maingi, M. Bell, D.A. Gates, J. C. Hosea, S.A. Sabbagh, R.J. Maqueda, E.D. Fredrickson, T.S. Bigelow, S.F. Paul, J.E. Menard, B.P. LeBlanc, L. R. Grisham, D. Mueller, H.W. Kugel, P.T. Bonoli, Stewart Zweben, Dan Stutman, R. Kaita, and James R. Wilson
Subjects: Physics, Toroid, Beta (plasma physics), Electron temperature, Torus, Plasma, Electric current, Magnetohydrodynamics, Atomic physics, Neutral beam injection
Abstract: The National Spherical Torus Experiment (NSTX) is a proof-of-principle experiment designed to study the physics of Spherical Tori (ST), i.e., low-aspect-ratio toroidal plasmas. Important issues for ST research are whether the high-eta stability and reduced transport theoretically predicted for this configuration can be realized experimentally. In NSTX, the commissioning of a digital real-time plasma control system, the provision of flexible heating systems, and the application of wall conditioning techniques were instrumental in achieving routine operation with good confinement. NSTX has produced plasmas with R/a {approx} 0.85 m/0.68 m, A {approx} 1.25, Ip * 1.1 MA, BT = 0.3-0.45 T, k * 2.2, d * 0.5, with auxiliary heating by up to 4 MW of High Harmonic Fast Waves, and 5 MW of 80 keV D0 Neutral Beam Injection (NBI). The energy confinement time in plasmas heated by NBI has exceeded 100 ms and a toroidal beta (bT = 2m0 /BT02, where BT0 is the central vacuum toroidal magnetic field) up to 22% has be en achieved. HHFW power of 2.3 MW has increased the electron temperature from an initial 0.4 keV to 0.9 keV both with and without producing a significant density rise in the plasma. The early application of both NBI and HHFW heating has slowed the penetration of the inductively produced plasma current, modifying the current profile and, thereby, the observed MHD stability.
Published: 2002

139. Spherical Torus Plasma Interactions with Large-area Liquid Lithium Surfaces in CDX-U

Author: P. C. Efthimion, G. Antar, H.W. Kugel, D. Hoffman, A. Post-Zwicker, Robert Kaita, R. Majeski, S. Luckhardt, Jonathan Menard, B. Jones, Rajesh Maingi, Tobin Munsat, Vlad Soukhanovskii, M. Maiorano, R. Woolley, Dan Stutman, G. Taylor, Sterling Smith, Leonid E. Zakharov, M. Boaz, J. Timberlake, R.P. Doerner, Michael Finkenthal, and J. Spaleta
Subjects: chemistry.chemical_compound, Toroid, chemistry, Limiter, chemistry.chemical_element, Torus, Neutron, Lithium, Vacuum chamber, Plasma, Boron carbide, Atomic physics
Abstract: The Current Drive Experiment-Upgrade (CDX-U) device at the Princeton Plasma Physics Laboratory (PPPL) is a spherical torus (ST) dedicated to the exploration of liquid lithium as a potential solution to reactor first-wall problems such as heat load and erosion, neutron damage and activation, and tritium inventory and breeding. Initial lithium limiter experiments were conducted with a toroidally-local liquid lithium rail limiter (L3) from the University of California at San Diego. Spectroscopic measurements showed a clear reduction of impurities in plasmas with the L3, compared to discharges with a boron carbide limiter. The evidence for a reduction in recycling was less apparent, however. This may be attributable to the relatively small area in contact with the plasma, and the presence of high-recycling surfaces elsewhere in the vacuum chamber. This conclusion was tested in subsequent experiments with a fully toroidal lithium limiter that was installed above the floor of the vacuum vessel. The new limiter covered over ten times the area of the L3 facing the plasma. Experiments with the toroidal lithium limiter have recently begun. This paper describes the conditioning required to prepare the lithium surface for plasma operations, and effect of the toroidal liquid lithium limiter on discharge performance.
Published: 2002

140. Characteristics of the FirstH-Mode Discharges in the National Spherical Torus Experiment

Author: B.P. LeBlanc, Yueng Kay Martin Peng, Dan Stutman, Stanley Kaye, David Johnson, F. Paoletti, M.G. Bell, C.H. Skinner, Ricardo Maqueda, Vlad Soukhanovskii, Jonathan Menard, A. L. Roquemore, C.E. Bush, Rajesh Maingi, E. J. Synakowski, H.W. Kugel, G. Taylor, David Gates, S.A. Sabbagh, D. Mueller, E.D. Fredrickson, R. E. Bell, Masayuki Ono, S.F. Paul, and Robert Kaita
Subjects: Physics, Nuclear physics, Scaling law, Mode (statistics), General Physics and Astronomy, Nanotechnology, National Spherical Torus Experiment, Beam (structure)
Abstract: Summary. —In summary, we have induced H -modedischarges in NSTX, in which the energy conﬁnementtime increased transiently by between 100% 200%.These H modes had energy conﬁnement well above ELM-free H -mode scaling laws, and had a signiﬁcantly greaterthreshold power than predicted. Thus H modes in NSTXwill eventually help extend the conﬁnement and thresholdpower scalings to low aspect ratio. Finally, H modes havebroader pressure proﬁles than L modes (e.g., the pressurepeaking factor was reduced by 15%in NSTX), andbroad proﬁles generally have higher b limits in tokamaksdue to improved low- n kink stability, e.g., TFTR [20] andDIII-D [21]. Thus achievement of H modes is a potentialpath for achieving higher b in NSTX.This research was supported by the U.S. Departmentof Energy under Contract No. DE-AC05-00OR22725,No. DE-AC02-76CH03073, No. W-7405-ENG-36, andGrant No. DE-FG02-99ER54524. We gratefully acknowl-edge the contribution of the NSTX technical staff and neu-tral beam operations staff, as well as useful discussionswith R. Akers, M. Gryaznevich, and A. Sykes from theMAST team.
Published: 2002

141. Conceptual design of a divertor Thomson scattering diagnostic for NSTX-U

Author: Adam McLean, Vlad Soukhanovskii, M. Ono, B.P. LeBlanc, B. Stratton, S.L. Allen, and T. N. Carlstrom
Subjects: Physics, Nuclear physics, Conceptual design, Heat flux, Scattering, Thomson scattering, Nuclear engineering, Divertor, Electron temperature, Plasma diagnostics, Inelastic scattering, Instrumentation
Abstract: A conceptual design for a divertor Thomson scattering (DTS) diagnostic has been developed for the NSTX-U device to operate in parallel with the existing multipoint Thomson scattering system. Higher projected peak heat flux in NSTX-U will necessitate application of advanced magnetics geometries and divertor detachment. Interpretation and modeling of these divertor scenarios will depend heavily on local measurement of electron temperature, Te, and density, ne, which DTS provides in a passive manner. The DTS design for NSTX-U adopts major elements from the successful DIII-D DTS system including 7-channel polychromators measuring Te to 0.5 eV. If implemented on NSTX-U, the divertor TS system would provide an invaluable diagnostic for the boundary program to characterize the edge plasma.
Published: 2014

142. Near-infrared spectroscopy for divertor plasma diagnosis and control in DIII-D tokamak

Author: Vlad Soukhanovskii, Adam McLean, and S.L. Allen
Subjects: Tokamak, Materials science, DIII-D, Thomson scattering, Divertor, Near-infrared spectroscopy, chemistry.chemical_element, law.invention, Neon, symbols.namesake, chemistry, Stark effect, law, symbols, Plasma diagnostics, Atomic physics, Instrumentation
Abstract: New near infrared (NIR) spectroscopic measurements performed in the DIII-D tokamak divertor plasma suggest new viable diagnostic applications: divertor recycling and low-Z impurity flux measurements, a spectral survey for divertor Thomson scattering (DTS) diagnostic, and Te monitoring for divertor detachment control. A commercial 0.3 m spectrometer coupled to an imaging lens via optical fiber and a InGaAs 1024 pixel array detector enabled deuterium and impurity emission measurements in the range 800-2300 nm. The first full NIR survey identified D, He, B, Li, C, N, O, Ne lines and provided plasma Te, ne estimates from deuterium Paschen and Brackett series intensity and Stark line broadening analysis. The range 1.000-1.060 mm was surveyed in high-density and neon seeded divertor plasmas for spectral background emission studies for λ = 1.064 μm laser-based DTS development. The ratio of adjacent deuterium Paschen-α and Brackett Br9 lines in recombining divertor plasmas is studied for divertor Te monitoring aimed at divertor detachment real-time feedback control.
Published: 2014

143. Effect of a deuterium gas puff on the edge plasma in NSTX

Author: D.P. Stotler, Vlad Soukhanovskii, Y. Sechrest, Stewart Zweben, R.J. Maqueda, Tobin Munsat, B.P. LeBlanc, W. Davis, R.E. Bell, E.T. Meier, S.M. Kaye, Yang Ren, David R. Smith, and S.A. Sabbagh
Subjects: Tokamak, Materials science, Turbulence, Plasma, Edge (geometry), Condensed Matter Physics, law.invention, Physics::Fluid Dynamics, Nuclear Energy and Engineering, Deuterium, law, Stored energy, Electron temperature, Light emission, Atomic physics, Astrophysics::Galaxy Astrophysics
Abstract: This paper describes a detailed examination of the effects of a relatively small pulsed deuterium gas puff on the edge plasma and edge turbulence in NSTX. This gas puff caused little or no change in the line-averaged plasma density or total stored energy, or in the edge density and electron temperature up to the time of the peak of the gas puff. The radial profile of the Dα light emission and the edge turbulence within this gas puff did not vary significantly over its rise and fall, implying that these gas puffs did not significantly perturb the local edge plasma or edge turbulence. These measurements are compared with modeling by DEGAS 2, UEDGE, and with simplified estimates for the expected effects of this gas puff.
Published: 2014

144. Comment on 'Magnetic geometry and physics of advanced divertors: The X-divertor and the snowflake' [Phys. Plasmas 20, 102507 (2013)]

Author: T D Rognlien, Vlad Soukhanovskii, Ronald H. Cohen, Dmitri Ryutov, and Maxim Umansky
Subjects: Physics, Pedestal, Divertor, Flux, Geometry, Plasma, Snowflake, Condensed Matter Physics, National Spherical Torus Experiment, Magnetic field
Abstract: In the recently published paper “Magnetic geometry and physics of advanced divertors: The X-divertor and the snowflake” [Phys. Plasmas 20, 102507 (2013)], the authors raise interesting and important issues concerning divertor physics and design. However, the paper contains significant errors: (a) The conceptual framework used in it for the evaluation of divertor “quality” is reduced to the assessment of the magnetic field structure in the outer Scrape-Off Layer. This framework is incorrect because processes affecting the pedestal, the private flux region and all of the divertor legs (four, in the case of a snowflake) are an inseparable part of divertor operation. (b) The concept of the divertor index focuses on only one feature of the magnetic field structure and can be quite misleading when applied to divertor design. (c) The suggestion to rename the divertor configurations experimentally realized on NSTX (National Spherical Torus Experiment) and DIII-D (Doublet III-D) from snowflakes to X-divertors is not justified: it is not based on comparison of these configurations with the prototypical X-divertor, and it ignores the fact that the NSTX and DIII-D poloidal magnetic field geometries fit very well into the snowflake “two-null” prescription.
Published: 2014

145. Edge transport studies in the edge and scrape-off layer of the National Spherical Torus Experiment with Langmuir probes

Author: R.J. Maqueda, Vlad Soukhanovskii, Lane Roquemore, Stewart Zweben, D.L. Rudakov, D.A. D'Ippolito, J.R. Myra, Neal Crocker, H.W. Kugel, R. Maingi, R.E. Bell, John Canik, Jose Boedo, J. W. Ahn, Nstx Team, and B.P. LeBlanc
Subjects: Physics, Radial velocity, Core (optical fiber), symbols.namesake, Amplitude, Turbulence, symbols, Particle, Langmuir probe, Flux, Plasma, Atomic physics, Condensed Matter Physics
Abstract: Transport and turbulence profiles were directly evaluated using probes for the first time in the edge and scrape-off layer (SOL) of NSTX [Ono et al., Nucl. Fusion 40, 557 (2000)] in low (L) and high (H) confinement, low power (Pin∼ 1.3 MW), beam-heated, lower single-null discharges. Radial turbulent particle fluxes peak near the last closed flux surface (LCFS) at ≈4×1021 s−1 in L-mode and are suppressed to ≈0.2×1021 s−1 in H mode (80%–90% lower) mostly due to a reduction in density fluctuation amplitude and of the phase between density and radial velocity fluctuations. The radial particle fluxes are consistent with particle inventory based on SOLPS fluid modeling. A strong intermittent component is identified. Hot, dense plasma filaments 4–10 cm in diameter, appear first ∼2 cm inside the LCFS at a rate of ∼1×1021 s−1 and leave that region with radial speeds of ∼3–5 km/s, decaying as they travel through the SOL, while voids travel inward toward the core. Profiles of normalized fluctuations feature levels o...
Published: 2014

146. Initial Studies of Core and Edge Transport of NSTX Plasmas

Author: William Dorland, C.E. Bush, E. J. Synakowski, G. Taylor, Dan Stutman, H.W. Kugel, Vlad Soukhanovskii, Clarisse Bourdelle, R.E. Bell, F. Paoletti, B.P. LeBlanc, R. Kaita, S. Kubota, David W. Johnson, M. G. Bell, S.M. Kaye, R.J. Maqueda, A. Rosenberg, J.E. Menard, M. Ono, E.D. Fredrickson, W. A. Peebles, Dennis Mueller, C.H. Skinner A.L. Roquemore, Akira Ejiri, Y-K.M. Peng, D.A. Gates, R. Maingi, S.A. Sabbagh, and D. S. Darrow
Subjects: Physics, Turbulence, Electron temperature, Electron, Plasma, Approx, Atomic physics, Scaling, Aspect ratio (image), Ion
Abstract: Rapidly developing diagnostic, operational, and analysis capability is enabling the first detailed local physics studies to begin in high-beta plasmas of the National Spherical Torus Experiment (NSTX). These studies are motivated in part by energy confinement times in neutral-beam-heated discharges that are favorable with respect to predictions from the ITER-89P scaling expression. Analysis of heat fluxes based on profile measurements with neutral-beam injection (NBI) suggest that the ion thermal transport may be exceptionally low, and that electron thermal transport is the dominant loss channel. This analysis motivates studies of possible sources of ion heating not presently accounted for by classical collisional processes. Gyrokinetic microstability studies indicate that long wavelength turbulence with k(subscript ''theta'') rho(subscript ''i'') {approx} 0.1-1 may be suppressed in these plasmas, while modes with k(subscript ''theta'') rho(subscript ''i'') {approx} 50 may be robust. High-harmonic fast-wave (HHFW) heating efficiently heats electrons on NSTX, and studies have begun using it to assess transport in the electron channel. Regarding edge transport, H-mode [high-confinement mode] transitions occur with either NBI or HHFW heating. The power required for low-confinement mode (L-mode) to H-mode transitions far exceeds that expected from empirical edge-localized-mode-free H-mode scaling laws derived from moderate aspect ratio devices. Finally, initial fluctuation measurements made with two techniques are permitting the first characterizations of edge turbulence.
Published: 2001

147. Effect of Boronization on Ohmic Plasmas in NSTX

Author: B.P. LeBlanc, S.M. Kaye, C.H. Skinner, R.E. Bell, J.E. Menard, D.A. Gates, Dennis Mueller, Vlad Soukhanovskii, William R. Wampler, S.F. Paul, Nobuhiro Nishino, H.K. Na, P. H. LaMarche, W. R. Blanchard, S.A. Sabbagh, H.W. Kugel, R. Maingi, and M. G. Bell
Subjects: Glow discharge, Ion beam analysis, Materials science, chemistry, Analytical chemistry, chemistry.chemical_element, Emission spectrum, Plasma, Atomic physics, Boron, Copper, Ohmic contact, Helium
Abstract: Boronization of the National Spherical Torus Experiment (NSTX) has enabled access to higher density, higher confinement plasmas. A glow discharge with 4 mTorr helium and 10% deuterated trimethyl boron deposited 1.7 g of boron on the plasma facing surfaces. Ion beam analysis of witness coupons showed a B+C areal density of 10 to the 18 (B+C) cm to the -2 corresponding to a film thickness of 100 nm. Subsequent ohmic discharges showed oxygen emission lines reduced by x15, carbon emission reduced by two and copper reduced to undetectable levels. After boronization, the plasma current flattop time increased by 70% enabling access to higher density, higher confinement plasmas.
Published: 2001

148. Characterization of divertor footprints and the pedestal plasmas in the presence of appliedn= 3 fields for the attached and detached conditions in NSTX

Author: Joon-Wook Ahn, S.M. Kaye, R.E. Bell, Vlad Soukhanovskii, Adam McLean, Kimin Kim, S.P. Gerhardt, John Canik, T.K. Gray, Ahmed Diallo, B.P. LeBlanc, Rajesh Maingi, Filippo Scotti, K. Tritz, and Jeremy Lore
Subjects: Toroid, Pedestal, Materials science, Nuclear Energy and Engineering, Field line, Divertor, Electron temperature, Plasma, Electron, Atomic physics, Condensed Matter Physics, Thermal diffusivity
Abstract: Recent progress in the study of 3D field effects on the divertor and pedestal plasmas is reported with the use of a new set of diagnostics. A wide angle visible camera provides 2D data of lower divertor surface covering almost the full range of radius (r) and toroidal angle (Φ), a significant advantage over the conventional 1D radial profile in examining non-axisymmetric effects of 3D fields on the divertor footprints. The spatial distribution of connection lengths (Lc) calculated by vacuum field line tracing in the presence of 3D fields (n = 3) agrees with the footprint pattern observed in the 2D wide angle camera images. The full (r, Φ) image data with high temporal resolution revealed that the spatial structure of modified divertor footprints is maintained even during the edge-localized modes (ELMs) triggered by applied n = 3 fields, when the ELM size is sufficiently small, i.e. the ELMs are 'phase locked' to the imposed perturbation field structure. This phase-lock is lost during the ELM rise time for ELMs with large energy loss, e.g. ΔWELM/WMHD > 4–5%. Divertor gas puff was used to create detached divertor condition and the effect of 3D fields on the detachment was investigated. The divertor remains partially detached with the 3D field application when a sufficient amount of gas is injected into the divertor region, which is accompanied by a noticeable drop of pedestal electron temperature (Te). However, with a lower gas puff, the divertor plasma re-attaches, when 3D fields were applied to the detached plasma, and the pedestal Te rises back up. There observed no other change in the pedestal profile associated with the re-attachment, indicating that this is likely to be dominated by a change in the electron thermal transport processes. A TRANSP analysis shows that the drop of pedestal electron heat diffusivity (χe) is responsible for this change but the source of this reduction is yet unclear.
Published: 2013

149. Diagnostics for liquid lithium experiments in CDX-U

Author: R.P. Doerner, Robert Kaita, S. Raftopoulos, B. Jones, P. C. Efthimion, R. Majeski, Vlad Soukhanovskii, Tobin Munsat, Rion A. Causey, Rajesh Maingi, H.W. Kugel, S. Luckhardt, Dan Stutman, G. Taylor, D. Hoffman, M. Iovea, Michael Finkenthal, and J. Timberlake
Subjects: Optics, Spectrometer, Chemistry, Thomson scattering, business.industry, Limiter, chemistry.chemical_element, Lithium, Plasma diagnostics, Plasma, Fusion power, business, Power density
Abstract: A flowing liquid lithium first wall or diverter target could virtually eliminate the concerns with power density and erosion, tritium retention, and cooling associated with solid walls in fusion reactors. To investigate the interaction of a spherical torus plasma with liquid lithium limiters, large area diverter targets, and walls, discharges will be established in the Current Drive Experiment-Upgrade (CDX-U) where the plasma-wall interactions are dominated by liquid lithium surfaces. Among the unique CDX-U lithium diagnostics is a multi-layer mirror (MLM) array, which will monitor the 135 {angstrom} LiIII line for core lithium concentrations. Additional spectroscopic diagnostics include a grazing incidence XUV spectrometer (STRS) and a filterscope system to monitor D{sub {alpha}} and various impurity lines local to the lithium limiter. Profile data will be obtained with a multichannel tangential bolometer and a multipoint Thomson scattering system configured to give enhanced edge resolution. Coupons on th e inner wall of the CDX-U vacuum vessel will be used for surface analysis. A 10,000 frame per second fast visible camera and an IR camera will also be available.
Published: 2000

150. Estimates of population inversion for deep-UV transitions in Kr-like Y, Zr, Nb, and Mo in a high-current reflex discharge

Author: M. J. May, Vlad Soukhanovskii, Kevin B. Fournier, Vyacheslav N. Shlyaptsev, William H. Goldstein, Michael Finkenthal, and Dan Stutman
Subjects: Chemistry, Excited state, Krypton, Analytical chemistry, chemistry.chemical_element, Plasma diagnostics, Atomic physics, Population inversion, Current density, Excitation, Spectral line, Ion
Abstract: Kr-like ions are good candidates for FUV lasing since they can be produced in plasmas quite easily. We present results from a spectroscopic investigation of Y IV emission from a high current density, cold cathode reflex discharge. The Y II to Y V emission is recorded in the 200-3000 {angstrom} range using photometrically calibrated spectrometers, while the emission of trace aluminum ions serves for plasma diagnostics. The intensities of the Y IV 4d - 5p and 5s - 5p transitions strongly increase relative to lines from Y II and Y III with increasing plasma current. The spectra studied here are obtained at a current density of 1.75 A/cm{sup 2}. Experimental Y IV intensity ratios spanning several excited configurations are compared with collisional radiative predictions of the HULLAC atomic physics package. Good agreement is found for the measured and predicted ratios of 4p{sup 5}5p to 4p{sup 5}5s level populations per statistical weight. Finally, the response of the Kr-like system to a fast, transient excitation pulse is examined using the RADEX code. Large transient gains are predicted for several 5s - 5p transitions in Y IV, Zr V, Nb VI and Mo VII.
Published: 1999

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