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194 results on '"Vlad Soukhanovskii"'

1. Spectroscopic measurement of increases in hydrogen molecular rotational temperature with plasma-facing surface temperature and due to collisional-radiative processes in tokamaks

Author: Nao Yoneda, Taiichi Shikama, Filippo Scotti, Kazuaki Hanada, Hiroki Iguchi, Hiroshi Idei, Takumi Onchi, Akira Ejiri, Takeshi Ido, Kaori Kono, Yi Peng, Yuki Osawa, Go Yatomi, Akihiro Kidani, Michihiro Kudo, Ryosuke Hiraka, Kosuke Takeda, Ronald E Bell, Anurag Maan, Dennis P Boyle, Richard P Majeski, Vlad Soukhanovskii, Mathias Groth, Adam G McLean, Robert S Wilcox, Charles Lasnier, K Nakamura, Yoshihiko Nagashima, Ryuya Ikezoe, Makoto Hasegawa, Kengoh Kuroda, Aki Higashijima, Takahiro Nagata, Shun Shimabukuro, Ichiro Niiya, Izumi Sekiya, and Masahiro Hasuo
Subjects: Nuclear and High Energy Physics, Condensed Matter Physics
Abstract: Spatially resolved rotational temperature of ground state hydrogen molecules desorbed from plasma-facing surface was measured in QUEST, LTX-β, and DIII-D tokamaks, and the increases of the rotational temperature with the surface temperature and due to collisional-radiative processes in the plasmas were evaluated. The increase due to collisional-radiative processes was calculated by solving rate equations considering electron and proton collisional excitation and deexcitation and spontaneous emission. The calculation results suggest a high sensitivity for the rotational temperature to electron and proton densities, but a negligible sensitivity to the electron, proton, and surface temperatures. In the three tokamaks with different plasma parameters and plasma facing surface materials, the spatial profile of the rotational temperature was estimated using Fulcher-α emission lines (600-608 nm). In QUEST, the spatial profile of the rotational temperature was estimated from spatially resolved spectra. In the other tokamaks, the rotational temperature was evaluated assuming a single point emission with a location determined from the Fulcher-α emission profile as measured with a filtered camera. In metal-walled devices QUEST and LTX-β, the rotational temperature increased with the surface temperature, and the calculated collisional-radiative increase is consistent with measured increase assuming that the rotational temperature at the surface is approximately 450 K higher than the surface temperature. In DIII-D with carbon walls, a larger collisional-radiative increase than the other tokamaks was observed because of the higher density leading to a large difference from the calculated increase compared to the other smaller tokamaks. Measurement of the Fulcher-α emission profile with higher spatial resolution in DIII-D may reduce the difference and reveal the effect of the surface temperature on the rotational temperature. These results shows the increases in the rotational temperature with the surface temperature and due to the collisional-radiative processes.
Published: 2023

2. NSTX-U theory, modeling and analysis results

Author: Walter Guttenfelder, D J Battaglia, Elena Belova, Nicola Bertelli, Mark D Boyer, Choong Seock Chang, Ahmed Diallo, Vinicius N Duarte, Fatima Ebrahimi, Eric Emdee, N Ferraro, Eric Fredrickson, Nikolai N Gorelenkov, William W Heidbrink, Zeki Ilhan, Stanley M Kaye, Eun-Hwa Kim, Andreas Kleiner, Florian M. Laggner, Mate Lampert, Jeff Lestz, Chang Liu, Deyong Liu, Tom Looby, Noah Mandell, Rajesh Maingi, James R Myra, Stefano Munaretto, Mario Podesta, Tariq Rafiq, Roger Raman, Matthew Reinke, Yang Ren, Juan Ruiz Ruiz, Filippo Scotti, Syun'ichi Shiraiwa, Vlad Soukhanovskii, Patrick Vail, Zhirui Wang, Will P Wehner, Anne E White, Roscoe B White, Benjamin J Q Woods, James Yang, Stewart Zweben, Santanu Banerjee, Robert Barchfeld, Ronald E Bell, John Berkery, Amitawa Bhattacharjee, Andreas Bierwage, Gustavo Paganini Canal, Xiang Chen, Cesar Fernando Clauser, Neal A Crocker, C W Domier, Todd E Evans, Manaure Francisquez, Kaifu Gan, Stefan P Gerhardt, Robert James Goldston, Travis K Gray, Ammar Hakim, Gregory W Hammett, Stephen C Jardin, Robert Kaita, Bruce E Koel, Egemen Kolemen, Seung-Hoe Ku, Shigeyuki Kubota, Benoit P LeBlanc, Fred Levinton, Jeremy D Lore, Neville C Luhmann, R. Lunsford, Ricardo Maqueda, Jonathan E Menard, Jacob H Nichols, Masayuki Ono, Jong-Kyu Park, Francesca M Poli, Terry L Rhodes, Juan Riquezes, Dave A Russell, Steve A Sabbagh, Eugenio Schuster, David Smith, Daren P Stotler, Brentley Stratton, Kevin Tritz, Weixing Wang, and Brian D Wirth
Subjects: Nuclear and High Energy Physics, TOKAMAKS, Condensed Matter Physics
Abstract: The mission of the low aspect ratio spherical tokamak NSTX-U is to advance the physics basis and technical solutions required for optimizing the configuration of next-step steady-state tokamak fusion devices. NSTX-U will ultimately operate at up to 2 MA of plasma current and 1 T toroidal field on axis for 5 seconds, and has available up to 15 MW of Neutral Beam Injection (NBI) power at different tangency radii and 6 MW of High Harmonic Fast Wave (HHFW) heating. With these capabilities NSTX-U will develop the physics understanding and control tools to ramp-up and sustain high performance fully non-inductive plasmas with large bootstrap fraction and enhanced confinement enabled via the low aspect ratio, high beta configuration. With its unique capabilities, NSTX-U research also supports ITER and other critical fusion development needs. Super-Alfvénic ions in beam-heated NSTX-U plasmas access energetic particle parameter space that is relevant for both -heated conventional and low aspect ratio burning plasmas. NSTX-U can also generate very large target heat fluxes to test conventional and innovative plasma exhaust and plasma facing component (PFC) solutions. This paper summarizes recent analysis, theory and modelling progress to advance the tokamak physics basis in the areas of macrostability and 3D fields, energetic particle stability and fast ion transport, thermal transport and pedestal structure, boundary and plasma material interaction, RF heating, scenario optimization and real-time control.
Published: 2022

3. Elimination of inter-discharge helium glow discharge cleaning with lithium evaporation in NSTX

Author: Robert Kaita, Filippo Scotti, Vlad Soukhanovskii, and R. Maingi
Subjects: Nuclear and High Energy Physics, Glow discharge, Materials Science (miscellaneous), Nuclear engineering, Analytical chemistry, Evaporation, chemistry.chemical_element, Ion temperature, Plasma, Electron, lcsh:TK9001-9401, 01 natural sciences, 010305 fluids & plasmas, Pedestal, Nuclear Energy and Engineering, chemistry, 0103 physical sciences, lcsh:Nuclear engineering. Atomic power, Lithium, 010306 general physics, Helium
Abstract: Operation in the National Spherical Torus Experiment (NSTX) typically used either periodic boronization and inter-shot helium glow discharge cleaning (HeGDC), or inter-shot lithium evaporation without boronization, and initially with inter-shot HeGDC. To assess the viability of operation without HeGDC, dedicated experiments were conducted in which Li evaporation was used while systematically shrinking the HeGDC between shots from the standard 10min to zero (10→6.5→4→0). Good shot reproducibility without HeGDC was achieved with lithium evaporations of 100mg or higher; evaporations of 200–300mg typically resulted in very low ELM frequency or ELM-free operation, reduced wall fueling, and improved energy confinement. The use of HeGDC before lithium evaporation modestly reduced Dα in the outer scrape-off layer, but not at the strike point. Pedestal electron and ion temperature also improved modestly, suggesting that HeGDC prior to lithium evaporation is a useful tool for experiments that seek to maximize plasma performance. Keywords: NSTX, Lithium, Recycling, Pedestal, Energy confinement
Published: 2017

4. Toroidal asymmetries in divertor impurity influxes in NSTX

Author: Adam McLean, Vlad Soukhanovskii, Joon-Wook Ahn, Filippo Scotti, and Robert Kaita
Subjects: Nuclear and High Energy Physics, Leading edge, Materials science, Toroid, Materials Science (miscellaneous), Divertor, chemistry.chemical_element, Plasma, 01 natural sciences, lcsh:TK9001-9401, 010305 fluids & plasmas, Nuclear Energy and Engineering, chemistry, Impurity, Physics::Plasma Physics, 0103 physical sciences, Dielectric heating, lcsh:Nuclear engineering. Atomic power, Lithium, Radio frequency, Atomic physics, 010306 general physics
Abstract: Toroidal asymmetries in divertor carbon and lithium influxes were observed in NSTX, due to toroidal differences in surface composition, tile leading edges, externally-applied three-dimensional (3D) fields and toroidally-localized edge plasma modifications due to radio frequency heating. Understanding toroidal asymmetries in impurity influxes is critical for the evaluation of total impurity sources, often inferred from measurements with a limited toroidal coverage. The toroidally-asymmetric lithium deposition induced asymmetries in divertor lithium influxes. Enhanced impurity influxes at the leading edge of divertor tiles were the main cause of carbon toroidal asymmetries and were enhanced during edge localized modes. Externally-applied 3D fields led to strike point splitting and helical lobes observed in divertor impurity emission, but marginal changes to the toroidally-averaged impurity influxes. Power coupled to the scrape-off layer SOL plasma during radio frequency (RF) heating of H-mode discharges enhanced impurity influxes along the non-axisymmetric divertor footprint of flux tubes connecting to plasma in front of the RF antenna. Keywords: NSTX, Divertor, Impurities, Sputtering, Toroidal asymmetry
Published: 2017

5. Effect of progressively increasing lithium conditioning on edge transport and stability in high triangularity NSTX H-modes

Author: B.P. LeBlanc, John Canik, Dennis Boyle, R. Maingi, Vlad Soukhanovskii, Ahmed Diallo, Filippo Scotti, S.A. Sabbagh, R.E. Bell, Robert Kaita, and S.M. Kaye
Subjects: Materials science, Mechanical Engineering, Evaporation, chemistry.chemical_element, Nanotechnology, Plasma, Electron, Thermal diffusivity, 01 natural sciences, 010305 fluids & plasmas, Pedestal, Nuclear Energy and Engineering, chemistry, 0103 physical sciences, Particle, General Materials Science, Lithium, Atomic physics, Elongation, 010306 general physics, Civil and Structural Engineering
Abstract: A sequence of H-mode discharges with increasing levels of pre-discharge lithium evaporation (‘dose’) was conducted in high triangularity and elongation boundary shape in NSTX. Energy confinement increased, and recycling decreased with increasing lithium dose, similar to a previous lithium dose scan in medium triangularity and elongation plasmas. Data-constrained SOLPS interpretive modeling quantified the edge transport change: the electron particle diffusivity decreased by 10–30x. The electron thermal diffusivity decreased by 4x just inside the top of the pedestal, but increased by up to 5x very near the separatrix. These results provide a baseline expectation for lithium benefits in NSTX-U, which is optimized for a boundary shape similar to the one in this experiment.
Published: 2017

6. Snowflake Divertor Experiments in the DIII-D, NSTX, and NSTX-U Tokamaks Aimed at the Development of the Divertor Power Exhaust Solution

Author: W.H. Meyer, C.J. Lasnier, Adam McLean, A.W. Hyatt, M.E. Fenstermacher, Egemen Kolemen, Vlad Soukhanovskii, S.P. Gerhardt, R. Maingi, M. A. Makowski, R.E. Bell, A. L. Roquemore, Robert Kaita, S.L. Allen, Ahmed Diallo, Roger Raman, Mario Podesta, E.T. Meier, Dmitri Ryutov, Jonathan Menard, A.W. Leonard, R. J. Groebner, B.P. LeBlanc, S.M. Kaye, Joon-Wook Ahn, T.H. Osborne, T.D. Rognlien, J.G. Watkins, T.W. Petrie, and Filippo Scotti
Subjects: Physics, Nuclear and High Energy Physics, Tokamak, DIII-D, Divertor, Spherical tokamak, Effective radiated power, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, law.invention, Nuclear physics, Pedestal, Heat flux, law, 0103 physical sciences, Radiative transfer, 010306 general physics
Abstract: Experimental results from the National Spherical Torus Experiment (NSTX), a medium-size spherical tokamak with a compact divertor, and DIII-D, a large conventional aspect ratio tokamak, demonstrate that the snowflake (SF) divertor configuration may provide a promising solution for mitigating divertor heat loads and target plate erosion compatible with core H-mode confinement in the future fusion devices, where the standard radiative divertor solution may be inadequate. In NSTX, where the initial high-power SF experiment was performed, the SF divertor was compatible with H-mode confinement, and led to the destabilization of large Edge Localized Modes (ELMs). However, a stable partial detachment of the outer strike point was also achieved where inter-ELM peak heat flux was reduced by factors 3–5, and peak ELM heat flux was reduced by up to 80% (see standard divertor). The DIII-D studies show the SF divertor enables significant power spreading in attached and radiative divertor conditions. Results include: compatibility with the core and pedestal, peak inter-ELM divertor heat flux reduction due to geometry at lower $n_{e}$ , and ELM energy and divertor peak heat flux reduction, especially prominent in radiative $D_{2}$ -seeded SF divertor, and nearly complete power detachment and broader radiated power distribution in the radiative $D_{2}$ -seeded SF divertor at $P_{\text {SOL}}=3-4$ MW. A variety of SF configurations can be supported by the divertor coil set in NSTX Upgrade. Edge transport modeling with the multifluid edge transport code UEDGE shows that the radiative SF divertor can successfully reduce peak divertor heat flux for the projected $P_{\text {SOL}} \simeq 9$ MW case. The radiative SF divertor with carbon impurity provides a wider $n_{e}$ operating window, 50% less argon is needed in the impurity-seeded SF configuration to achieve similar $q_{\text {peak}}$ reduction factors (see standard divertor).
Published: 2016

7. Role of transport versus fueling upon pedestal density (Q4 Report and Final Report)

Author: Aaron Rosenthal, Tony Leonard, Tom Osborne, Jerry Hughes, Vlad Soukhanovskii, Ahmed Diallo, L. Casali, Auna Moser, Huiqian Wang, Rich Groebner, Aaron Sontag, Florian Laggner, Oak Nelson, Saskia Mordijck, Filippo Scotti, and Richard Reksoatmodjo
Subjects: Pedestal, Materials science, Mechanics
Published: 2019

8. Observation of He-like satellite lines of the H-like potassium K XIX emission

Author: Gregory V. Brown, M. P. Hill, Tom Lockard, J. Nilsen, Vlad Soukhanovskii, D. Burridge, Ronnie Shepherd, L. M. R. Hobbs, Michael E. Weller, L. A. Wilson, John J. L. Morton, P. W. Hatfield, S. J. Rose, A. McKelvey, Peter Beiersdorfer, David Hoarty, and AWE Plc
Subjects: 010504 meteorology & atmospheric sciences, Dark matter, TRANSITIONS, Astrophysics, Astronomy & Astrophysics, 01 natural sciences, dark matter, Spectral line, methods: laboratory: atomic, law.invention, law, 0201 Astronomical and Space Sciences, 0103 physical sciences, atomic data, SPECTRA, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, 0306 Physical Chemistry (incl. Structural), Physics, Science & Technology, Spectrometer, Astronomy and Astrophysics, Plasma, plasmas, Laser, Wavelength, Space and Planetary Science, X-rays: galaxies: clusters, Physical Sciences, 0202 Atomic, Molecular, Nuclear, Particle and Plasma Physics, Electron temperature, Satellite, techniques: spectroscopic
Abstract: We present measurements of the H-like potassium (K xix) X-ray spectrum and its He-like (K xviii) satellite lines, which are situated in the wavelength region between 3.34 and 3.39 Å, which has been of interest for the detection of dark matter. The measurements were taken with a high-resolution X-ray spectrometer from targets irradiated by a long-pulse (2 ns) beam from the Orion laser facility. We obtain experimental wavelength values of dielectronic recombination satellite lines and show that the ratio of the Lyα lines and their dielectronic satellite lines can be used to estimate the electron temperature, which in our case was about 1.5 ± 0.3 keV.
Published: 2019

9. Fusion Energy Sciences FY 2017 Joint Research Target (JRT) Summary Milestone Report

Author: Vlad Soukhanovskii, Brian LaBombard, and S.L. Allen
Subjects: Joint research, Materials science, Systems engineering, Milestone (project management), Fusion power
Published: 2017

10. Dependence of recycling and edge profiles on lithium evaporation in high triangularity, high performance NSTX H-mode discharges

Author: H.W. Kugel, John Canik, Vlad Soukhanovskii, Ahmed Diallo, B.P. LeBlanc, Dennis Boyle, C.H. Skinner, S.A. Sabbagh, R. Maingi, R.E. Bell, Robert Kaita, M.G. Bell, S.M. Kaye, and T.H. Osborne
Subjects: Nuclear and High Energy Physics, Divertor, Evaporation, Analytical chemistry, chemistry.chemical_element, Plasma, Edge (geometry), Nuclear Energy and Engineering, chemistry, Stack (abstract data type), General Materials Science, Lithium, Graphite, Atomic physics, Deposition (chemistry)
Abstract: In this paper, the effects of a pre-discharge lithium evaporation variation on highly shaped discharges in the National Spherical Torus Experiment (NSTX) are documented. Lithium wall conditioning (‘dose’) was routinely applied onto graphite plasma facing components between discharges in NSTX, partly to reduce recycling. Reduced Dα emission from the lower and upper divertor and center stack was observed, as well as reduced midplane neutral pressure; the magnitude of reduction increased with the pre-discharge lithium dose. Improved energy confinement, both raw τE and H-factor normalized to scalings, with increasing lithium dose was also observed. At the highest doses, we also observed elimination of edge-localized modes. The midplane edge plasma profiles were dramatically altered, comparable to lithium dose scans at lower shaping, where the strike point was farther from the lithium deposition centroid. As a result, this indicates that the benefits of lithium conditioning should apply to the highly shaped plasmas planned in NSTX-U.
Published: 2015

11. Application of the radiating divertor approach to innovative tokamak divertor concepts

Author: Adam McLean, R. Maingi, Egemen Kolemen, W. M. Solomon, T.W. Petrie, C.J. Lasnier, C. T. Holcomb, Vlad Soukhanovskii, R.A. Moyer, T.C. Luce, R.J. La Haye, R. J. Groebner, J.G. Watkins, M.E. Fenstermacher, A.W. Leonard, Francesca Turco, and S.L. Allen
Subjects: Nuclear and High Energy Physics, Materials science, Tokamak, Nuclear engineering, Divertor, chemistry.chemical_element, Plasma, law.invention, Nuclear physics, Neon, Materials Science(all), Nuclear Energy and Engineering, Heat flux, chemistry, law, General Materials Science
Abstract: We survey the results of recent DIII-D experiments that tested the effectiveness of three innovative tokamak divertor concepts in reducing divertor heat flux while still maintaining acceptable energy confinement under neon/deuterium-based radiating divertor (RD) conditions: (1) magnetically unbalanced high performance double-null divertor (DND) plasmas, (2) high performance double-null “Snowflake” (SF-DN) plasmas, and (3) single-null H-mode plasmas having different isolation from their divertor targets. In general, all three concepts adapt well to RD conditions, achieving significant reduction in divertor heat flux ( q ⊥ p ) and maintaining high performance metrics, e.g., 50–70% reduction in peak divertor heat flux for DND and SF-DN plasmas that are characterized by β N ≅ 3.0 and H 98(y,2) ≈ 1.35. It is also demonstrated that q ⊥ p could be reduced ≈50% by extending the parallel connection length ( L ||-XPT ) in the scrape-off layer between the X -point and divertor targets over a variety of the RD and non-RD environments tested.
Published: 2015

12. Modeling detachment physics in the NSTX snowflake divertor

Author: Robert Kaita, T.D. Rognlien, Filippo Scotti, E.T. Meier, Vlad Soukhanovskii, Adam McLean, R.E. Bell, Mario Podesta, B.P. LeBlanc, and Ahmed Diallo
Subjects: Physics, Power loss, Nuclear and High Energy Physics, Tokamak, Nuclear engineering, Divertor, Wetted area, law.invention, Heat flux, Partial saturation, Materials Science(all), Nuclear Energy and Engineering, law, General Materials Science, Snowflake, Atomic physics, National Spherical Torus Experiment
Abstract: The snowflake divertor is a proposed technique for coping with the tokamak power exhaust problem in next-step experiments and eventually reactors, where extreme power fluxes to material surfaces represent a leading technological and physics challenge. In lithium-conditioned National Spherical Torus Experiment (NSTX) discharges, application of the snowflake divertor typically induced partial outer divertor detachment and severalfold heat flux reduction. UEDGE is used to analyze and compare conventional and snowflake divertor configurations in NSTX. Matching experimental upstream profiles and divertor measurements in the snowflake requires target recycling of 0.97 vs. 0.91 in the conventional case, implying partial saturation of the lithium-based pumping mechanism. Density scans are performed to analyze the mechanisms that facilitate detachment in the snowflake, revealing that increased divertor volume provides most of the parallel heat flux reduction. Also, neutral gas power loss is magnified by the increased wetted area in the snowflake, and plays a key role in generating volumetric recombination.
Published: 2015
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13. Heat flux management via advanced magnetic divertor configurations and divertor detachment

Author: Vlad Soukhanovskii, D.A. Humphreys, Egemen Kolemen, S.L. Allen, R. Maingi, M. A. Makowski, Adam McLean, Ezekial A Unterberg, A.W. Hyatt, A.W. Leonard, B.D. Bray, M.E. Fenstermacher, Raffi Nazikian, T.W. Petrie, and C.J. Lasnier
Subjects: Nuclear and High Energy Physics, Materials science, Control algorithm, Materials Science(all), Nuclear Energy and Engineering, Heat flux, Position (vector), Electromagnetic coil, Divertor, General Materials Science, Mechanics, Snowflake, Control methods
Abstract: The snowflake divertor (SFD) control and detachment control to manage the heat flux at the divertor are successfully demonstrated at DIII-D. Results of the development and implementation of these two heat flux reduction control methods are presented. The SFD control algorithm calculates the position of the two null-points in real-time and controls shaping coil currents to achieve and stabilize various snowflake configurations. Detachment control stabilizes the detachment front fixed at specified distance between the strike point and the X-point throughout the shot.
Published: 2015

14. Lithium sputtering from lithium-coated plasma facing components in the NSTX divertor

Author: Robert Kaita, E.T. Meier, Filippo Scotti, Adam McLean, Mario Podesta, Vlad Soukhanovskii, Joon-Wook Ahn, R.E. Bell, Michael Jaworski, S.P. Gerhardt, A. L. Roquemore, and H.W. Kugel
Subjects: Nuclear and High Energy Physics, Materials science, Divertor, Analytical chemistry, chemistry.chemical_element, Plasma, Materials Science(all), Nuclear Energy and Engineering, chemistry, Impurity, Sputtering, Molybdenum, Melting point, General Materials Science, Lithium, Graphite
Abstract: Lithium sputtering yields and gross impurity influxes from lithium-coated graphite and molybdenum plasma facing components (PFCs) have been analyzed for the first time in the National Spherical Torus Experiment (NSTX) divertor during H-mode NBI-heated discharges. Motivated by the beneficial effects of lithium conditioning on discharge performance and reproducibility, evaporative lithium coatings were the routine wall conditioning technique in NSTX. Neutral lithium sputtering yields from solid lithium coatings in NSTX were found to be consistent with values reported from test stand experiments from deuterium-saturated lithium (with sputtering yields Y Li ∼0.03–0.07 Y Li ∼ 0.03 – 0.07 ). Temperature-enhanced lithium sputtering was observed on lithium-coated graphite and molybdenum as a result of PFC heating by both embedded heaters and incident plasma heat flux, leading to Y Li ∼0.1–0.2 Y Li ∼ 0.1 – 0.2 for surface temperatures above the lithium melting point.
Published: 2015

15. Radiative snowflake divertor studies in DIII-D

Author: C.J. Lasnier, Adam McLean, Vlad Soukhanovskii, R. J. Groebner, A.W. Hyatt, Egemen Kolemen, M.E. Fenstermacher, S.L. Allen, T.H. Osborne, D. N. Hill, A.W. Leonard, T.W. Petrie, M. A. Makowski, and W.H. Meyer
Subjects: Range (particle radiation), Nuclear and High Energy Physics, DIII-D, Chemistry, Divertor, Flux, Heat flux, Materials Science(all), Nuclear Energy and Engineering, Radiative transfer, General Materials Science, Snowflake, Atomic physics, Edge-localized mode
Abstract: Recent DIII-D experiments assessed the snowflake divertor (SF) configuration in a radiative regime in H-mode discharges with D 2 D 2 seeding. The SF configuration was maintained for many energy confinement times (2–3 s) in H-mode discharges ( I p =1.2 I p = 1.2 MA, P NBI =4–5 P NBI = 4 – 5 MW, and B×∇B B × ∇ B down (favorable direction toward the divertor)), and found to be compatible with high performance operation (H98y2 ⩾ 1). The two studied SF configurations, the SF-plus and the SF-minus, have a small finite distance between the primary X-point and the secondary B p B p null located in the private flux region or the common flux region, respectively. In H-mode discharges with the SF configurations (cf. H-mode discharges with the standard divertor with similar conditions) the stored energy lost per the edge localized mode (ELM) was reduced, and significant divertor heat flux reduction between and during ELMs was observed over a range of collisionalities, from lower density conditions toward a higher density H-modes with the radiative SF divertor.
Published: 2015
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16. Electron pressure balance in the SOL through the transition to detachment

Author: Vlad Soukhanovskii, S.L. Allen, D. N. Hill, J.G. Watkins, Ezekial A Unterberg, B.D. Bray, C. Liu, P.C. Stangeby, T.H. Osborne, J.A. Boedo, A.W. Leonard, David Eldon, Adam McLean, M.E. Fenstermacher, M A Makowski, T.W. Petrie, M. Groth, C.K. Tsui, A.R. Briesemeister, C.J. Lasnier, and T.N. Carlstrom
Subjects: Nuclear and High Energy Physics, Tokamak, ta214, Convective heat transfer, ta114, Thomson scattering, Chemistry, Divertor, ta221, Plasma, Electron, Mechanics, law.invention, Core (optical fiber), Materials Science(all), Nuclear Energy and Engineering, law, Pressure balance, General Materials Science, Atomic physics, tokamaks, ta218
Abstract: Upgrades to core and divertor Thomson scattering (DTS) diagnostics at DIII-D have provided measurements of electron pressure profiles in the lower divertor from attached- to fully-detached divertor plasma conditions. Detailed, multistep sequences of discharges with increasing line-averaged density were run at several levels of Pinj. Strike point sweeping allowed 2D divertor characterization using DTS optimized to measure Te down to 0.5 eV. The ionization front at the onset of detachment is found to move upwards in a controlled manner consistent with the indication that scrape-off layer parallel power flux is converted from conducted to convective heat transport. Measurements of ne, Te and pe in the divertor versus Lparallel demonstrate a rapid transition from Te ⩾ 15 eV to ⩽3 eV occurring both at the outer strike point and upstream of the X-point. These observations provide a strong benchmark for ongoing modeling of divertor detachment for existing and future tokamak devices.
Published: 2015

17. Multi-Fluid Transport Modeling of NSTX Upgrade Standard and Snowflake Divertor Configurations

Author: Vlad Soukhanovskii, E.T. Meier, S. Gerhardt, Jonathan Menard, and T D Rognlien
Subjects: Materials science, Nuclear engineering, Divertor, chemistry.chemical_element, Cryopump, Plasma, Condensed Matter Physics, Fluid transport, Nuclear physics, Neon, chemistry, Heat flux, Radiative transfer, Snowflake
Abstract: In NSTX Upgrade (NSTX-U), power exhaust is expected to challenge available material and heat removal technologies, which are limited to ∼10 MW/m2. Preliminary analysis of heat flux mitigation strategies, including the snowflake divertor configuration and radiative divertor operation, is performed with the multi-fluid edge transport code, UEDGE. Divertor recycling between 95% and 99%, and power exhaust between 7 and 9 MW are explored. Compared to the standard divertor, the particular snowflake divertor studied here strongly reduces outer target heat flux, but tends to have higher (>10 MW/m2) inner target heat flux. This suggests that snowflake divertor optimization should be pursued in future work. Both neon and argon impurity seeding scenarios mitigate high heat fluxes in both standard and snowflake configurations, but argon can cause radiative collapse of the core plasma at only 3% concentration. Divertor cryopumping is also considered, and modeling shows ∼50% more particle removal with the snowflake divertor. (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim)
Published: 2014

18. Real-time radiative divertor feedback control development for the NSTX-U tokamak using a vacuum ultraviolet spectrometer

Author: Vlad Soukhanovskii, Robert Kaita, and B. Stratton
Subjects: Tokamak, Materials science, Spectrometer, Divertor, chemistry.chemical_element, Plasma, 01 natural sciences, 010305 fluids & plasmas, law.invention, Neon, chemistry, law, 0103 physical sciences, Radiative transfer, Plasma diagnostics, Atomic physics, 010306 general physics, Instrumentation, Line (formation)
Abstract: A radiative divertor technique is planned for the NSTX-U tokamak to prevent excessive erosion and thermal damage of divertor plasma-facing components in H-mode plasma discharges with auxiliary heating up to 12 MW. In the radiative (partially detached) divertor, extrinsically seeded deuterium or impurity gases are used to increase plasma volumetric power and momentum losses. A real-time feedback control of the gas seeding rate is planned for discharges of up to 5 s duration. The outer divertor leg plasma electron temperature Te estimated spectroscopically in real time will be used as a control parameter. A vacuum ultraviolet spectrometer McPherson Model 251 with a fast charged-coupled device detector is developed for temperature monitoring between 5 and 30 eV, based on the Δn = 0, 1 line intensity ratios of carbon, nitrogen, or neon ion lines in the spectral range 300–1600 A. A collisional-radiative model-based line intensity ratio will be used for relative calibration. A real-time Te-dependent signal within a characteristic divertor detachment equilibration time of ∼10–15 ms is expected.
Published: 2016

19. Tokamak Power Exhaust with the Snowflake Divertor: Present Results and Outstanding Issues

Author: X. Xu and Vlad Soukhanovskii
Subjects: Physics, Nuclear and High Energy Physics, Tokamak, Null (radio), Divertor, Nuclear engineering, Plasma, 01 natural sciences, 010305 fluids & plasmas, law.invention, Power (physics), Nuclear physics, Nuclear Energy and Engineering, law, 0103 physical sciences, Nuclear fusion, Poloidal field, Snowflake, 010306 general physics
Abstract: A snowflake divertor magnetic configuration (Ryutov in Phys Plasmas 14(6):064502, 2007) with the second-order poloidal field null offers a number of possible advantages for tokamak plasma heat and particle exhaust in comparison with the standard poloidal divertor with the first-order null. Results from snowflake divertor experiments are briefly reviewed and future directions for research in this area are outlined.
Published: 2015

20. Characterization of fueling NSTX H-mode plasmas diverted to a liquid lithium divertor

Author: S.P. Gerhardt, Vlad Soukhanovskii, J. Kallman, A. L. Roquemore, Jean Paul Allain, Adam McLean, Chase N. Taylor, Tyler Abrams, M. Ono, S.F. Paul, B.P. LeBlanc, Roger Raman, B. Heim, Michael Jaworski, C.H. Skinner, R.E. Bell, Robert Kaita, Leonid E. Zakharov, D. Mueller, Mario Podesta, S.A. Sabbagh, S.M. Kaye, Richard E. Nygren, D.K. Mansfield, H.W. Kugel, Ahmed Diallo, Jonathan Menard, Rajesh Maingi, Filippo Scotti, and M.G. Bell
Subjects: Nuclear and High Energy Physics, Divertor, Evaporation, Analytical chemistry, chemistry.chemical_element, Plasma, Nuclear Energy and Engineering, Deuterium, chemistry, General Materials Science, Lithium, Graphite, Carbon, Liquid lithium
Abstract: Deuterium fueling experiments were conducted with the NSTX Liquid Lithium Divertor (LLD). Lithium evaporation recoated the LLD surface to approximate flowing liquid Li to sustain D retention. In the first experiment with the diverted outer strike point on the LLD, the difference between the applied D gas input and the plasma D content reached very high values without disrupting the plasma, as would normally occur in the absence of Li pumping, and there was also little change in plasma D content. In the second experiment, constant fueling was applied, as the LLD temperature was varied to change the surface from solid to liquid. The D retention was relatively constant, and about the same as that for solid Li coatings on graphite, or twice that achieved without Li PFC coatings. Contamination of the LLD surface was also possible due to compound formation and erosion and redeposition from carbon PFCs.
Published: 2013

21. Effect of n=3 perturbation field amplitudes below the ELM triggering threshold on edge and SOL transport in NSTX

Author: Adam McLean, Vlad Soukhanovskii, Joon-Wook Ahn, Jeremy Lore, Kevin Tritz, Michael Jaworski, G. J. Kramer, Alessandro Bortolon, John Canik, E.D. Fredrickson, Rajesh Maingi, and Filippo Scotti
Subjects: Physics, Nuclear and High Energy Physics, Divertor, Perturbation (astronomy), Observable, Plasma, Computational physics, Flux (metallurgy), Amplitude, Nuclear Energy and Engineering, Physics::Plasma Physics, General Materials Science, Neutron, Atomic physics, Magnetohydrodynamics
Abstract: Here, the pulsed application of n = 3 magnetic perturbation fields with amplitudes below that which triggers ELMs results in distinct, transient responses observable on several edge and divertor diagnostics in NSTX. We refer to these responses as Sub-Threshold Edge Perturbations (STEPs). An analysis of edge measurements suggests that STEPs result in increased transport in the plasma edge and scrape-off layer, which leads to augmentation of the intrinsic strike point splitting due to error fields, i.e., an intensification of the helical divertor footprint flux pattern. These effects are much smaller in magnitude than those of triggered ELMs, and are observed for the duration of the field perturbation measured internal to the vacuum vessel. In addition, STEPs are correlated with changes to the MHD activity, along with transient reductions in the neutron production rate. Ideally the STEPs could be used to provide density control and prevent impurity accumulation, in the same manner that on-demand ELM triggering is used on NSTX, without the impulsive divertor fluxes and potential for damage to plasma facing components associated with ELMs.
Published: 2013

22. Observation of non-Maxwellian electron distributions in the NSTX divertor

Author: Michael Jaworski, Robert Kaita, J. Kallman, H.W. Kugel, Vlad Soukhanovskii, Adam McLean, T.K. Gray, S.A. Sabbagh, D.P. Stotler, Filippo Scotti, M.G. Bell, I. Kaganovich, and B.P. LeBlanc
Subjects: Nuclear and High Energy Physics, Tokamak, Chemistry, Divertor, Plasma, Electron, Kinetic energy, law.invention, Characterization (materials science), symbols.namesake, Nuclear Energy and Engineering, law, symbols, Langmuir probe, General Materials Science, Atomic physics
Abstract: The scrape-off layer plasma at the tokamak region is characterized by open field lines and often contains large variations in plasma properties along these field-lines. Proper characterization of local plasma conditions is critical to assessing plasma–material interaction processes occurring at the target. Langmuir probes are frequently employed in tokamak divertors but are challenging to interpretation. A kinetic interpretation for Langmuir probes in NSTX has yielded non-Maxwellian electron distributions in the divertor characterized by cool bulk populations and energetic tail populations with temperatures of 2–4 times the bulk. Spectroscopic analysis and modeling confirms the bulk plasma temperature and density which can only be obtained with the kinetic interpretation.
Published: 2013

23. Study of non-axisymmetric divertor footprints using 2-D IR and visible cameras and a 3-D heat conduction solver in NSTX

Author: Vlad Soukhanovskii, John Canik, Joon-Wook Ahn, Kaifu Gan, Adam McLean, Rajesh Maingi, Filippo Scotti, Jeremy Lore, A. L. Roquemore, and T.K. Gray
Subjects: Physics, Nuclear and High Energy Physics, Toroid, Field (physics), Field line, media_common.quotation_subject, Divertor, Rotational symmetry, Analytical chemistry, Thermal conduction, Asymmetry, Computational physics, Nuclear Energy and Engineering, Heat flux, Physics::Plasma Physics, General Materials Science, media_common
Abstract: Toroidally non-axisymmetric divertor profiles during the 3-D field application and for ELMs are studied with simultaneous observation by a new wide angle visible camera and a high speed IR camera. A newly implemented 3-D heat conduction code, TACO, is used to obtain divertor heat flux. The wide angle camera data confirmed the previously reported result on the validity of vacuum field line tracing on the prediction of split strike point pattern by 3-D fields as well as the phase locking of ELM heat flux to the 3-D fields. TACO calculates the 2-D heat flux distribution allowing assessment of toroidal asymmetry of peak heat flux and heat flux width. The degree of asymmetry ( e DA ) is defined to quantify the asymmetric heat deposition on the divertor surface and is found to have a strong positive dependence on peak heat flux.
Published: 2013

24. Measurement and modeling of surface temperature dynamics of the NSTX liquid lithium divertor

Author: Rajesh Maingi, Vlad Soukhanovskii, Richard E. Nygren, T.K. Gray, Adam McLean, Tyler Abrams, Michael Jaworski, Joon-Wook Ahn, Kaifu Gan, C.H. Skinner, Robert Kaita, and H.W. Kugel
Subjects: Surface (mathematics), Nuclear and High Energy Physics, Materials science, Infrared, Divertor, Analytical chemistry, Radius, Plasma, Nuclear Energy and Engineering, Heat flux, Melting point, General Materials Science, Graphite, Atomic physics
Abstract: Dual-band infrared (IR) measurements of the National Spherical Torus eXperiment (NSTX) Liquid Lithium Divertor (LLD) are reported that demonstrate liquid Li is more effective at removing plasma heat flux than Li-conditioned graphite. Extended dwell of the outer strike point (OSP) on the LLD caused an incrementally larger area to be heated above the Li melting point through the discharge leading to enhanced D retention and plasma confinement. Measurement of Tsurface near the OSP demonstrates a significant reduction of the LLD surface temperature compared to that of Li-coated graphite at the same major radius. Modeling of these data with a 2-D simulation of the LLD structure in the DFLUX code suggests that the structure of the LLD was successful at handling up to q⊥,peak = 5 MW/m2 inter-ELM and up to 10 MW/m2 during ELMs from its plasma-facing surface as intended, and provide an innovative method for inferring the Li layer thickness.
Published: 2013

25. Advanced divertor configurations with large flux expansion

Author: Stefano Coda, Ahmed Diallo, Thomas Morgan, Vlad Soukhanovskii, Adam McLean, Rajesh Maingi, B. P. Duval, B. Tal, Filippo Scotti, JJ Jakub Zielinski, Benoit Labit, B.P. LeBlanc, Egemen Kolemen, R.E. Bell, Waj Wouter Vijvers, Robert Kaita, G. P. Canal, G. De Temmerman, R Rajiv Raman, S.F. Paul, S.P. Gerhardt, Mario Podesta, S.M. Kaye, Dmitri Ryutov, A. L. Roquemore, Jonathan Menard, H. Reimerdes, D. Mueller, and Science and Technology of Nuclear Fusion
Subjects: Nuclear and High Energy Physics, Materials science, Tokamak, snowflake divertor, Divertor, Nuclear engineering, Plasma, Spherical tokamak, law.invention, Pedestal, Nuclear Energy and Engineering, Heat flux, law, General Materials Science, TCV, Atomic physics, Magnetohydrodynamics, Snowflake, plasma
Abstract: Experimental studies of the novel snowflake divertor concept (D. Ryutov, Phys. Plasmas 14 (2007) 064502) performed in the NSTX and TCV tokamaks are reviewed in this paper. The snowflake divertor enables power sharing between divertor strike points, as well as the divertor plasma-wetted area, effective connection length and divertor volumetric power loss to increase beyond those in the standard divertor, potentially reducing heat flux and plasma temperature at the target. It also enables higher magnetic shear inside the separatrix, potentially affecting pedestal MHD stability. Experimental results from NSTX and TCV confirm the predicted properties of the snowflake divertor. In the NSTX, a large spherical tokamak with a compact divertor and lithium-coated graphite plasma-facing components (PFCs), the snowflake divertor operation led to reduced core and pedestal impurity concentration, as well as reappearance of Type I ELMs that were suppressed in standard divertor H-mode discharges. In the divertor, an otherwise inaccessible partial detachment of the outer strike point with an up to 50% increase in divertor radiation and a peak divertor heat flux reduction from 3-7 MW/m(2) to 0.5-1 MW/m(2) was achieved. Impulsive heat fluxes due to Type-I ELMs were significantly dissipated in the high magnetic flux expansion region. In the TCV, a medium-size tokamak with graphite PFCs, several advantageous snowflake divertor features (cf. the standard divertor) have been demonstrated: an unchanged L-H power threshold, enhanced stability of the peeling-ballooning modes in the pedestal region (and generally an extended second stability region), as well as an H-mode pedestal regime with reduced (x2-3) Type I ELM frequency and slightly increased (20-30%) normalized ELM energy, resulting in a favorable average energy loss comparison to the standard divertor. In the divertor, ELM power partitioning between snowflake divertor strike points was demonstrated. The NSTX and TCV experiments are providing support for the snowflake divertor as a viable solution for the outstanding tokamak plasma-material interface issues. (C) 2013 Elsevier B.V. All rights reserved.
Published: 2013

26. Developing and validating advanced divertor solutions on DIII-D for next-step fusion devices

Author: D.L. Rudakov, C.P. Chrobak, T.D. Rognlien, G.D. Porter, Tyler Abrams, Daniel Thomas, C.J. Lasnier, Chaofeng Sang, Adam McLean, A.W. Leonard, Huarong Du, P.C. Stangeby, Vlad Soukhanovskii, Ezekial A Unterberg, A.R. Briesemeister, M. A. Makowski, Aaro Järvinen, Brett H. Meyer, Igor Bykov, Auna Moser, David Eldon, Jeremy Lore, Rui Ding, Richard E. Nygren, M. Groth, David Donovan, Oliver Schmitz, Jerome Guterl, Brent Covele, J.A. Boedo, T.W. Petrie, Cameron Samuell, H. Si, William R. Wampler, Larry W Owen, Aaron Sontag, Egemen Kolemen, D. Elder, R.P. Doerner, J.G. Watkins, D. N. Hill, Dean A. Buchenauer, Huiqian Wang, Houyang Guo, S.L. Allen, Ane Lasa, John Canik, and E.T. Hinson
Subjects: Nuclear and High Energy Physics, Fusion, Computational model, DIII-D, Computer science, Nuclear engineering, Divertor, Predictive capability, Plasma, Fusion power, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, plasma-material interactions, advanced tokamak, Physical structure, divertor concept, 0103 physical sciences, fusion reactor, 010306 general physics
Abstract: A major challenge facing the design and operation of next-step high-power steady-state fusion devices is to develop a viable divertor solution with order-of-magnitude increases in power handling capability relative to present experience, while having acceptable divertor target plate erosion and being compatible with maintaining good core plasma confinement. A new initiative has been launched on DIII-D to develop the scientific basis for design, installation, and operation of an advanced divertor to evaluate boundary plasma solutions applicable to next step fusion experiments beyond ITER. Developing the scientific basis for fusion reactor divertor solutions must necessarily follow three lines of research, which we plan to pursue in DIII-D: (1) Advance scientific understanding and predictive capability through development and comparison between state-of-the art computational models and enhanced measurements using targeted parametric scans; (2) Develop and validate key divertor design concepts and codes through innovative variations in physical structure and magnetic geometry; (3) Assess candidate materials, determining the implications for core plasma operation and control, and develop mitigation techniques for any deleterious effects, incorporating development of plasma-material interaction models. These efforts will lead to design, installation, and evaluation of an advanced divertor for DIII-D to enable highly dissipative divertor operation at core density (n e/n GW), neutral fueling and impurity influx most compatible with high performance plasma scenarios and reactor relevant plasma facing components (PFCs). This paper highlights the current progress and near-term strategies of boundary/PMI research on DIII-D.
Published: 2016

27. A dual wavelength imaging system for plasma-surface interaction studies on the National Spherical Torus Experiment Upgrade

Author: Vlad Soukhanovskii and Filippo Scotti
Subjects: Physics, medicine.medical_specialty, Tokamak, Orders of magnitude (temperature), business.industry, Divertor, Spectral imaging, law.invention, Optics, Optical path, Physics::Plasma Physics, law, medicine, Lithium Tokamak Experiment, Plasma diagnostics, Image sensor, business, Instrumentation
Abstract: A two-channel spectral imaging system based on a charge injection device radiation-hardened intensified camera was built for studies of plasma-surface interactions on divertor plasma facing components in the National Spherical Torus Experiment Upgrade (NSTX-U) tokamak. By means of commercially available mechanically referenced optical components, the two-wavelength setup images the light from the plasma, relayed by a fiber optic bundle, at two different wavelengths side-by-side on the same detector. Remotely controlled filter wheels are used for narrow bandpass and neutral density filters on each optical path allowing for simultaneous imaging of emission at wavelengths differing in brightness up to 3 orders of magnitude. Applications on NSTX-U will include the measurement of impurity influxes in the lower divertor strike point region and the imaging of plasma-material interaction on the head of the surface analysis probe MAPP (Material Analysis and Particle Probe). The diagnostic setup and initial results from its application on the lithium tokamak experiment are presented.
Published: 2016

28. Exploration of magnetic perturbation effects on advanced divertor configurations in NSTX-U

Author: Vlad Soukhanovskii, Todd Evans, Y. Feng, Heinke Frerichs, I. Waters, G. P. Canal, and Oliver Schmitz
Subjects: Physics, Steady state (electronics), Divertor, Flux, Plasma, Mechanics, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Magnetic field, Heat flux, Physics::Plasma Physics, 0103 physical sciences, Symmetry breaking, Atomic physics, 010306 general physics, Axial symmetry
Abstract: The control of divertor heat loads—both steady state and transient—remains a key challenge for the successful operation of ITER and FNSF. Magnetic perturbations provide a promising technique to control ELMs (Edge Localized Modes) (transients), but understanding their detailed impact is difficult due to their symmetry breaking nature. One approach for reducing steady state heat loads is so called “advanced divertors” which aim at optimizing the magnetic field configuration: the snowflake and the (super-)X-divertor. It is likely that both concepts—magnetic perturbations and advanced divertors—will have to work together, and we explore their interaction based on the NSTX-U setup. An overview of different divertor configurations under the impact of magnetic perturbations is presented, and the resulting impact on plasma edge transport is investigated with the EMC3-EIRENE code. Variations in size of the magnetic footprint of the perturbed separatrix are found, which are related to the level of flux expansion on the divertor target. Non-axisymmetric peaking of the heat flux related to the perturbed separatrix is found at the outer strike point, but only in locations where flux expansion is not too large.
Published: 2016

29. Recent progress of NSTX lithium program and opportunities for magnetic fusion research

Author: Vlad Soukhanovskii, J. Hosea, M. Ono, Siye Ding, M.G. Bell, V. Surla, Brian Nelson, H.W. Kugel, Roger Raman, Leonid E. Zakharov, Robert Kaita, Joon-Wook Ahn, W. Guttenfelder, P.M. Ryan, Howard Yuh, Rajesh Maingi, Filippo Scotti, S.F. Paul, S.M. Kaye, C.H. Skinner, Adam McLean, Jonathan Menard, Jean Paul Allain, Michael Jaworski, John Canik, R.E. Bell, D.K. Mansfield, D. Muller, D. J. Battaglia, S.A. Sabbagh, J. Kallman, Yang Ren, T.K. Gray, Richard E. Nygren, S.P. Gerhardt, B.P. LeBlanc, J. Timberlake, and Chase N. Taylor
Subjects: Materials science, Mechanical Engineering, Divertor, Nuclear engineering, Pellets, Evaporation, chemistry.chemical_element, Nanotechnology, Plasma, Electron, Pedestal, Nuclear Energy and Engineering, chemistry, Deuterium, General Materials Science, Lithium, Civil and Structural Engineering
Abstract: Lithium wall coating techniques have been experimentally explored on National Spherical Torus Experiment (NSTX) for the last six years. The lithium experimentation on NSTX started with a few milligrams of lithium injected into the plasma as pellets and it has evolved to a dual lithium evaporation system which can evaporate up to ∼160 g of lithium onto the lower divertor plates between re-loadings. The unique feature of the NSTX lithium research program is that it can investigate the effects of lithium coated plasma-facing components in H-mode divertor plasmas. This lithium evaporation system has produced many intriguing and potentially important results. In 2010, the NSTX lithium program has focused on the effects of liquid lithium divertor (LLD) surfaces including the divertor heat load, deuterium pumping, impurity control, electron thermal confinement, H-mode pedestal physics, and enhanced plasma performance. To fill the LLD with lithium, 1300 g of lithium was evaporated into the NSTX vacuum vessel during the 2010 operations. The routine use of lithium in 2010 has significantly improved the plasma shot availability resulting in a record number of plasma shots in any given year. In this paper, as a follow-on paper from the 1st lithium symposium [1] , we review the recent progress toward developing fundamental understanding of the NSTX lithium experimental observations as well as the opportunities and associated R&D required for use of lithium in future magnetic fusion facilities including ITER.
Published: 2012

30. Characterization of transient particle loads during lithium experiments on the National Spherical Torus Experiment

Author: Vlad Soukhanovskii, David N. Ruzic, T.K. Gray, Michael Jaworski, Adam McLean, Filippo Scotti, V. Surla, Robert Kaita, J. Kallman, and H.W. Kugel
Subjects: Tokamak, Materials science, Mechanical Engineering, Divertor, Energy flux, Flux, Temperature measurement, Computational physics, law.invention, symbols.namesake, Nuclear Energy and Engineering, law, symbols, Particle, Langmuir probe, General Materials Science, Neutral particle, Civil and Structural Engineering
Abstract: Transient events such as Edge Localized Modes (ELMs) or disruptions can lead to large particle and power loads on the divertor plates of tokamak experiments. These events can cause significant erosion and are detrimental to the lifetime of the plasma facing components. Understanding the impact of ELMs remains a complex problem and a major challenge. In this study, an effort is made to characterize these ELMs and other transients based on their characteristics using a particle flux probe and surface temperature measurements from a dual-band IR camera. Typically, the temporal evolution of an ELM from the particle flux probe is characterized by a steep rise and a gradual decrease of current signal. This burst like structure is seen by the Langmuir probes as a rise in the ion saturation current with a width of a few milliseconds. This study entails gathering statistics of typical ELM-like events for various shots in order to assess the typical loading of ELMs on the Liquid Lithium Divertor (LLD) that was installed in the FY10 run campaign. Later, the power deposition profiles during ELMs are also characterized from IR camera measurements for certain discharges to find that only 15% of the energy flux arrives at the divertor target before the surface temperature reached its maximum value. Finally, a correlation was found between the particle flux from the probes during the ELMs and the neutral particle flux from Dα signal indicating the utility of the particle flux probe as a means to characterize ELMs.
Published: 2012

31. NSTX plasma operation with a Liquid Lithium Divertor

Author: J. Kallman, Robert Kaita, Chase N. Taylor, M.G. Bell, D. Mueller, M. Viola, Richard E. Nygren, Vlad Soukhanovskii, S.P. Gerhardt, H. Schneider, Adam McLean, S.M. Kaye, Jonathan Menard, J. Timberlake, B. Heim, Ahmed Diallo, Jean Paul Allain, M. Ono, Robert Ellis, A. L. Roquemore, C.H. Skinner, R. Raman, R.E. Bell, Rajesh Maingi, H.W. Kugel, S.A. Sabbagh, B.P. LeBlanc, Leonid E. Zakharov, Michael Jaworski, and S.F. Paul
Subjects: Materials science, Mechanical Engineering, Nuclear engineering, Divertor, Evaporation, chemistry.chemical_element, Plasma, Nuclear Energy and Engineering, chemistry, Molybdenum, Lithium Tokamak Experiment, General Materials Science, Lithium, Graphite, Wetting, Civil and Structural Engineering
Abstract: NSTX 2010 experiments were conducted using a molybdenum Liquid Lithium Divertor (LLD) surface installed on the outer part of the lower divertor. This tested the effectiveness of maintaining the deuterium retention properties of a static liquid lithium surface when refreshed by lithium evaporation as an approximation to a flowing liquid lithium surface. The LLD molybdenum front face has a 45% porosity to provide sufficient wetting to spread 37 g of lithium, and to retain it in the presence of magnetic forces. Lithium Evaporators were used to deposit lithium on the LLD surface. At the beginning of discharges, the LLD lithium surface ranged from solid to liquefied depending on the amount of applied and plasma heating. Noteworthy improvements in plasma performance were obtained similar to those obtained previously with lithiated graphite, e.g., ELM-free, quiescent edge, H-modes. During these experiments with the plasma outer strike point on the LLD, the rate of deuterium retention in the LLD, as indicated by the fueling needed to achieve and maintain stable plasma conditions, was the about the same as that for solid lithium coatings on the graphite prior to the installation of the LLD, i.e., about two times that of no-lithium conditions. The role of lithium impurities in this result is discussed. Following the 2010 experimental campaign, inspection of the LLD found mechanical damage to the plate supports, and other hardware resulting from forces following plasma current disruptions. The LLD was removed, upgraded, and reinstalled. A row of molybdenum tiles was installed inboard of the LLD for 2011 experiments with both inner and outer strike points on lithiated molybdenum to allow investigation of lithium plasma facing issues encountered in the first testing of the LLD.
Published: 2012

32. Modification of the electron energy distribution function during lithium experiments on the National Spherical Torus Experiment

Author: M.G. Bell, Robert Kaita, B.P. LeBlanc, H.W. Kugel, Vlad Soukhanovskii, Adam McLean, J. Kallman, T.K. Gray, Michael Jaworski, S.A. Sabbagh, D.P. Stotler, and V. Surla
Subjects: education.field_of_study, Materials science, Mechanical Engineering, Divertor, Population, chemistry.chemical_element, Electron, Plasma, Kinetic energy, symbols.namesake, Nuclear Energy and Engineering, chemistry, symbols, Langmuir probe, Electron temperature, General Materials Science, Lithium, Atomic physics, education, Civil and Structural Engineering
Abstract: The National Spherical Torus Experiment (NSTX) has recently studied the use of a liquid lithium divertor (LLD). Divertor Langmuir probes have also been installed for making measurements of the local plasma conditions. A non-local probe interpretation method is used to supplement the classical probe interpretation and obtain measurements of the electron energy distribution function (EEDF) which show the occurrence of a hot-electron component. Analysis is made of two discharges within a sequence that exhibited changes in plasma fueling efficiency. It is found that the local electron temperature increases and that this increase is most strongly correlated with the energy contained within the hot-electron population. Preliminary interpretative modeling indicates that kinetic effects are likely in the NSTX.
Published: 2012

33. Measurements and 2-D modeling of recycling and edge transport in discharges with lithium-coated PFCs in NSTX

Author: Vlad Soukhanovskii, T.H. Osborne, R.E. Bell, H.W. Kugel, B.P. LeBlanc, Rajesh Maingi, and John Canik
Subjects: Nuclear and High Energy Physics, Edge density, Divertor, chemistry.chemical_element, Plasma, Edge (geometry), Nuclear Energy and Engineering, chemistry, Heat flux, Particle, General Materials Science, Lithium, Atomic physics, Plasma density
Abstract: The application of lithium coatings on plasma facing components has been shown to profoundly affect plasma performance in the National Spherical Torus Experiment, improving energy confinement and eliminating edge-localized modes. The edge particle balance during these ELM-free discharges has been studied through 2-D plasma-neutrals modeling, constrained by measurements of the upstream plasma density and temperature profiles and the divertor heat flux and Dα emission. The calculations indicate that the reduction in divertor Dα emission with lithium coatings applied is consistent with a drop in recycling coefficient from R ∼ 0.98 to R ∼ 0.9. The change in recycling is not sufficient to account for the change in edge density profiles: interpretive modeling indicates similar transport coefficients within the edge transport barrier (D/χe ∼ 0.2/1.0 m2/s), but a widening of the barrier with lithium.
Published: 2011

34. NSTX plasma response to lithium coated divertor

Author: B.P. LeBlanc, S.A. Sabbagh, Jean Paul Allain, Robert Kaita, Vlad Soukhanovskii, S.P. Gerhardt, J. Kallman, M.G. Bell, C.H. Skinner, Roger Raman, William R. Wampler, S.M. Kaye, Leonid E. Zakharov, D. Mueller, H. Schneider, Richard Majeski, A. L. Roquemore, R.J. Maqueda, J. Timberlake, Siye Ding, Richard E. Nygren, R.E. Bell, Michael Jaworski, Chase N. Taylor, D.K. Mansfield, S.F. Paul, Stewart Zweben, H.W. Kugel, and Rajesh Maingi
Subjects: Nuclear and High Energy Physics, Materials science, Divertor, chemistry.chemical_element, Electron, Plasma, Effective radiated power, Ion, Nuclear Energy and Engineering, chemistry, Impurity, General Materials Science, Lithium, Graphite, Atomic physics
Abstract: NSTX experiments have explored lithium evaporated on a graphite divertor and other plasma-facing components in both L- and H- mode confinement regimes heated by high-power neutral beams. Improvements in plasma performance have followed these lithium depositions, including a reduction and eventual elimination of the HeGDC time between discharges, reduced edge neutral density, reduced plasma density, particularly in the edge and the SOL, increased pedestal electron and ion temperature, improved energy confinement and the suppression of ELMs in the H-mode. However, with improvements in confinement and suppression of ELMs, there was a significant secular increase in the effective ion charge Zeff and the radiated power in H-mode plasmas as a result of increases in the carbon and medium-Z metallic impurities. Lithium itself remained at a very low level in the plasma core
Published: 2011

35. Deuterium retention in NSTX with lithium conditioning

Author: Vlad Soukhanovskii, Chase N. Taylor, Rajesh Maingi, C.H. Skinner, Lane Roquemore, H.W. Kugel, W. Blanchard, and Jean Paul Allain
Subjects: Nuclear and High Energy Physics, Analytical chemistry, chemistry.chemical_element, Ionic bonding, Plasma, Outgassing, Nuclear Energy and Engineering, X-ray photoelectron spectroscopy, chemistry, Deuterium, General Materials Science, Lithium, Graphite, Carbon
Abstract: High (approximate to 90%) deuterium retention was observed in NSTX gas balance measurements both with- and without lithiumization of the carbon plasma-facing components. The gas retained in ohmic discharges was measured by comparing the vessel pressure rise after a discharge to that of a gas-only pulse with the pumping valves closed. For neutral beam heated discharges the gas input and gas pumped by the NB cryopanels were tracked. The discharges were followed by outgassing of deuterium that reduced the retention. The relationship between retention and surface chemistry was explored with a new plasma-material interface probe connected to an in vacuo surface science station that exposed four material samples to the plasma. XPS and TDS analysis demonstrated that binding of D atoms in graphite is fundamentally changed by lithium - in particular atoms are weakly bonded in regions near lithium atoms bound to either oxygen or the carbon matrix. This is in contrast to the strong ionic bonding that occurs between D and pure Li. (C) 2010 Elsevier B.V. All rights reserved.
Published: 2011

36. Reduction of low-Z impurities during plasma start-up

Author: D. Mueller, M.G. Bell, Vlad Soukhanovskii, B. A. Nelson, Lane Roquemore, H.W. Kugel, Thomas Jarboe, Roger Raman, and B.P. LeBlanc
Subjects: Nuclear and High Energy Physics, Tokamak, Divertor, chemistry.chemical_element, Solenoid, Electron, Plasma, law.invention, Nuclear Energy and Engineering, chemistry, Physics::Plasma Physics, law, Impurity, General Materials Science, Lithium, Coaxial, Atomic physics
Abstract: Reduction of low-Z impurities is essential during the plasma start-up in tokamaks. For plasma start-up using the method of Coaxial Helicity Injection (CHI) it has been found that conventional wall conditioning methods have been inadequate to generate a plasma with acceptably low levels of low-Z impurities. NSTX has now used a new combination of techniques to improve CHI start-up performance. These are the use of high-current discharge cleaning of the lower divertor surfaces, which function as the CHI electrodes, to remove loosely bound impurities, controlling the poloidal magnetic field to avoid plasma wall contact and the use of evaporated lithium coatings of the electrodes and other plasma-facing surfaces. Together, these techniques have enabled significant improvement in NSTX CHI performance leading to a saving of central solenoid flux and the first observation of electron temperatures during CHI exceeding the oxygen radiation barrier temperature.
Published: 2011

37. Characteristics of divertor heat and particle deposition with intrinsic and applied 3-D fields in NSTX H-mode plasmas

Author: Rajesh Maingi, Vlad Soukhanovskii, Jeremy Lore, Adam McLean, John Canik, Jong-Kyu Park, Joon-Wook Ahn, T.K. Gray, and A. L. Roquemore
Subjects: Physics, Nuclear and High Energy Physics, Field (physics), Field line, Divertor, Flux, Plasma, Computational physics, Nuclear Energy and Engineering, Heat flux, Physics::Plasma Physics, Electromagnetic coil, General Materials Science, Atomic physics, Particle deposition
Abstract: Divertor heat and particle flux profiles are modified by externally imposed non-axisymmetric magnetic perturbations in the National Spherical Torus Experiment. The applied 3-D field causes strike point splitting that is represented as local peaks and valleys in the divertor profiles. The plasma response in an ideal perturbed equilibrium approach was included in the field line tracing by taking account of the B-field generated by the plasma current up to a certain fraction of normalized flux inside the separatrix and being superposed to the vacuum field. The inclusion of this type of plasma response does not significantly affect the location and spacing of the split strike points at the divertor surface. A modest level of divertor profile modification is found to occur even without the application of 3-D fields in certain high triangularity (δ = 0.65–0.8) discharges, with the location of local peaks and valleys same before and after the application. The intrinsic error field from the non-circularity of PF5 coil is known to have primarily n = 3 component in NSTX and was modeled to be included in the vacuum field line tracing. The produced puncture plot of the field line along with the connection length profile shows that the radial location of local peaks agrees well with the measurement, identifying intrinsic error field as a possible source of intrinsic strike point splitting. The radial location of local peaks in the profiles during the triggered ELM by the applied n = 3 field is the same before and after the 3-D field application. This shows that the heat flux from the triggered ELMs appears to follow the imposed n = 3 field structure.
Published: 2011

38. 'Snowflake' divertor configuration in NSTX

Author: H.W. Kugel, A. L. Roquemore, Jonathan Menard, Egemen Kolemen, Vlad Soukhanovskii, R.J. Maqueda, Adam McLean, D. Mueller, R.E. Bell, Robert Kaita, Joon-Wook Ahn, Dmitri Ryutov, Rajesh Maingi, Howard A. Scott, David Gates, Roger Raman, S.F. Paul, B.P. LeBlanc, and S.P. Gerhardt
Subjects: Nuclear and High Energy Physics, Tokamak, Materials science, Nuclear engineering, Divertor, chemistry.chemical_element, Plasma, law.invention, Core (optical fiber), Nuclear Energy and Engineering, Heat flux, chemistry, law, General Materials Science, Lithium, Atomic physics, Snowflake, Magnetohydrodynamics
Abstract: Steady-state handling of divertor heat flux is a critical issue for present and future conventional and spherical tokamaks with compact high power density divertors. A novel “snowflake” divertor (SFD) configuration that takes advantage of magnetic properties of a second-order poloidal null has been predicted to have a larger plasma-wetted area and a larger divertor volume, in comparison with a standard first-order poloidal X-point divertor configuration. The SFD was obtained in 0.8 MA, 4–6 MW NBI-heated H-mode discharges in NSTX using two divertor magnetic coils. The SFD led to a partial detachment of the outer strike point even in low-collisionality scrape-off layer plasma obtained with lithium coatings in NSTX. Significant divertor peak heat flux reduction and impurity screening have been achieved simultaneously with good core confinement and MHD properties.
Published: 2011

39. Observation and modeling of inner divertor re-attachment in discharges with lithium coatings in NSTX

Author: Robert Kaita, Vlad Soukhanovskii, Filippo Scotti, Howard A. Scott, H.W. Kugel, M.L. Adams, and A. L. Roquemore
Subjects: Nuclear and High Energy Physics, Electron density, Chemistry, Thermodynamic equilibrium, Divertor, chemistry.chemical_element, Balmer series, Plasma, symbols.namesake, Nuclear Energy and Engineering, Stark effect, Ionization, symbols, General Materials Science, Lithium, Atomic physics
Abstract: In the National Spherical Torus Experiment (NSTX), modifications to the inner divertor plasma regimes are observed in high triangularity, H-mode, NBI heated discharges due to lithium coatings evaporated on the plasma facing components. In particular, the drop in the recombination rate, the reduced neutral pressure and the reduced electron density (inferred from Stark broadening measurements of high-n deuterium Balmer lines) suggested that the inner divertor, which is usually detached in discharges without lithium, re-attached. Experimental results are compared to simulations obtained with a 1D partially ionized plasma transport model integrated in the non-local thermodynamic equilibrium radiation transport code CRETIN to understand how the reduced recycling affects the divertor parameters in NSTX discharges with lithium coatings.
Published: 2011

40. Dependence of divertor heat flux widths on heating power, flux expansion, and plasma current in the NSTX

Author: Rajesh Maingi, Vlad Soukhanovskii, Joon-Wook Ahn, Adam McLean, J.E. Surany, and T.K. Gray
Subjects: Nuclear and High Energy Physics, Chemistry, Infrared, Divertor, Analytical chemistry, Flux, chemistry.chemical_element, Lambda, Magnetic flux, Nuclear Energy and Engineering, Heat flux, General Materials Science, Lithium, Atomic physics, Electric current
Abstract: We report the dependence of the lower divertor surface heat flux profiles, measured from infrared thermography and mapped magnetically to the mid-plane on loss power into the scrape-off layer (P{sub LOSS}), plasma current (I{sub p}), and magnetic flux expansion (f{sub exp}), as well as initial results with lithium wall conditioning in NSTX. Here we extend previous studies [R. Maingi et al., J. Nucl. Mater. 363-365 (2007) 196-200] to higher triangularity similar to 0.7 and higher I{sub p} {le} 1.2 MA. First we note that the mid-plane heat flux width mapped to the mid-plane, {lambda}{sub q}{sup mid} is largely independent of P{sub LOSS} for P{sub LOSS} {ge} 4 MW. {lambda}{sub q}{sup mid} is also found to be relatively independent of f{sub exp}; peak heat flux is strongly reduced as f{sub exp} is increased, as expected. Finally, {lambda}{sub q}{sup mid} is shown to strongly contract with increasing I{sub p} such that {lambda}{sub q}{sup mid} {alpha} I{sub p}{sup -1.6} with a peak divertor heat flux of q{sub div,peak} similar to 15 MW/m{sup 2} when I{sub p} = 1.2 MA and P{sub LOSS} similar to 6 MW. These relationships are then used to predict the divertor heat flux for the planned NSTX-Upgrade, with heatingmore » power between 10 and 15 MW, B{sub t} = 1.01 and I{sub p}= 2.0 MA for 5 s.« less
Published: 2011

41. The impact of lithium wall coatings on NSTX discharges and the engineering of the Lithium Tokamak eXperiment (LTX)

Author: S.P. Gerhardt, M.G. Bell, D.P. Stotler, J. Timberlake, Erik Granstedt, Rajesh Maingi, R.E. Bell, D.K. Mansfield, G. V. Pereverzev, Vlad Soukhanovskii, J. Kallman, Robert Kaita, B.P. LeBlanc, Leonid E. Zakharov, S.M. Kaye, L. Berzak, S.F. Paul, H. Schneider, Richard Majeski, T. A. Kozub, T.K. Gray, S. Avasarala, Peter Beiersdorfer, D.P. Lundberg, T. Strickler, H.W. Kugel, C.M. Jacobson, and J. K. Lepson
Subjects: Liquid metal, Tokamak, Materials science, Mechanical Engineering, Nuclear engineering, Divertor, Magnetic confinement fusion, chemistry.chemical_element, Fusion power, Spherical tokamak, law.invention, Nuclear Energy and Engineering, chemistry, law, Lithium Tokamak Experiment, General Materials Science, Lithium, Civil and Structural Engineering
Abstract: Recent experiments on the National Spherical Torus eXperiment (NSTX) have shown the benefits of solid lithium coatings on carbon PFC's to diverted plasma performance, in both L- and H-mode confinement regimes. Better particle control, with decreased inductive flux consumption, and increased electron temperature, ion temperature, energy confinement time, and DD neutron rate were observed. Successive increases in lithium coverage resulted in the complete suppression of ELM activity in H-mode discharges. A liquid lithium divertor (LLD), which will employ the porous molybdenum surface developed for the LTX shell, is being installed on NSTX for the 2010 run period, and will provide comparisons between liquid walls in the Lithium Tokamak eXperiment (LTX) and liquid divertor targets in NSTX. LTX, which recently began operations at the Princeton Plasma Physics Laboratory, is the world's first confinement experiment with full liquid metal plasma-facing components (PFCs). All materials and construction techniques in LTX are compatible with liquid lithium. LTX employs an inner, heated, stainless steel-faced liner or shell, which will be lithium-coated. In order to ensure that lithium adheres to the shell, it is designed to operate at up to 500–600 °C to promote wetting of the stainless by the lithium, providing the first hot wall in a tokamak to operate at reactor-relevant temperatures. The engineering of LTX will be discussed.
Published: 2010

42. Implications of NSTX lithium results for magnetic fusion research

Author: John Canik, Roger Raman, R.E. Bell, C.H. Skinner, Vlad Soukhanovskii, Robert Kaita, S.F. Paul, Jonathan Menard, M.G. Bell, S. J. Diem, M. Ono, Rajesh Maingi, H.W. Kugel, G. Taylor, S.M. Kaye, S.A. Sabbagh, D.K. Mansfield, J. C. Hosea, B.P. LeBlanc, and S.P. Gerhardt
Subjects: Materials science, Tokamak, Mechanical Engineering, Divertor, Nuclear engineering, chemistry.chemical_element, Plasma, Fusion power, law.invention, Nuclear physics, Nuclear Energy and Engineering, chemistry, law, Beta (plasma physics), Dielectric heating, General Materials Science, Lithium, Magnetohydrodynamics, Civil and Structural Engineering
Abstract: Lithium wall coating techniques have been experimentally explored on NSTX for the last five years. The lithium experimentation on NSTX started with a few milligrams of lithium injected into the plasma as pellets and it has evolved to a lithium evaporation system which can evaporate up to ~ 100 g of lithium onto the lower divertor plates between lithium reloadings. The unique feature of the lithium research program on NSTX is that it can investigate the effects of lithium in H-mode divertor plasmas. This lithium evaporation system thus far has produced many intriguing and potentially important results; the latest of these are summarized in a companion paper by H. Kugel. In this paper, we suggest possible implications and applications of the NSTX lithium results on the magnetic fusion research which include electron and global energy confinement improvements, MHD stability enhancement at high beta, ELM control, H-mode power threshold reduction, improvements in radio frequency heating and non-inductive plasma start-up performance, innovative divertor solutions and improved operational efficiency.
Published: 2010

43. Lithium coatings on NSTX plasma facing components and its effects on boundary control, core plasma performance, and operation

Author: S.A. Sabbagh, Vlad Soukhanovskii, Roger Raman, B.P. LeBlanc, R.E. Bell, M. Ono, Robert Kaita, S.F. Paul, S.M. Kaye, D.K. Mansfield, M.G. Bell, C.H. Skinner, J. Timberlake, Rajesh Maingi, Richard E. Nygren, S.P. Gerhardt, J. Kallman, D. Mueller, Leonid E. Zakharov, H. Schneider, Jonathan Menard, Jean Paul Allain, and H.W. Kugel
Subjects: Materials science, Mechanical Engineering, Divertor, Nuclear engineering, chemistry.chemical_element, Plasma, Fusion power, Nuclear Energy and Engineering, Nuclear reactor core, chemistry, General Materials Science, Lithium, Graphite, Deposition (law), Evaporator, Civil and Structural Engineering
Abstract: NSTX high power divertor plasma experiments have used in succession lithium pellet injection (LPI), evaporated lithium, and injected lithium powder to apply lithium coatings to graphite plasma facing components. In 2005, following the wall conditioning and LPI, discharges exhibited edge density reduction and performance improvements. Since 2006, first one, and now two lithium evaporators have been used routinely to evaporate lithium onto the lower divertor region at total rates of 10-70 mg/min for periods 5-10 min between discharges. Prior to each discharge, the evaporators are withdrawn behind shutters. Significant improvements in the performance of NBI heated divertor discharges resulting from these lithium depositions were observed. These evaporators are now used for more than 80% of NSTX discharges. Initial work with injecting fine lithium powder into the edge of NBI heated deuterium discharges yielded comparable changes in performance. Several operational issues encountered with lithium wall conditions, and the special procedures needed for vessel entry are discussed. The next step in this work is installation of a liquid lithium divertor surface on the outer part of the lower divertor.
Published: 2010

44. Divertor leg filaments in NSTX-U

Author: Filippo Scotti, James Myra, Vlad Soukhanovskii, Stewart Zweben, and D. A. Baver
Subjects: Physics, Nuclear and High Energy Physics, Divertor, Nuclear engineering, 0103 physical sciences, 010306 general physics, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas
Published: 2018

45. Multi-Fluid Modeling of Low-Recycling Divertor Regimes

Author: C.H. Skinner, M.E. Rensink, Vlad Soukhanovskii, Rajesh Maingi, Sergei Krasheninnikov, A. Yu. Pigarov, R.E. Bell, H.W. Kugel, D.P. Stotler, T.D. Rognlien, and Roman Smirnov
Subjects: Materials science, Divertor, chemistry.chemical_element, Plasma, Mechanics, Edge (geometry), Condensed Matter Physics, Instability, Deuterium, chemistry, Impurity, Electron temperature, Lithium, Atomic physics
Abstract: The low-recycling regimes of divertor operation in a single-null NSTX magnetic configuration are studied using computer simulations with the edge plasma transport code UEDGE. The edge plasma transport properties pertinent to the low-recycling regimes are demonstrated. These include the flux-limited character of the parallel heat transport and the high plasma temperatures with the flattened profiles in the scrape-off-layer. It is shown that to maintain the balance of particle fluxes at the core interface the deuterium gas puffing rate should increase as the divertor recycling coefficient decreases. The radial profiles of the heat load to the outer divertor plate, the upstream radial plasma profiles, and the effects of the cross-field plasma transport in the low-recycling regimes are discussed. It is also shown that recycling of lithium impurities evaporating from the divertor plate at high surface temperatures can reverse the low-recycling divertor operational regime to the high-recycling one and may cause thermal instability of the divertor plate. (C) 2010 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
Published: 2010

46. Initial development of the DIII–D snowflake divertor control

Author: Adam McLean, Rajesh Maingi, Egemen Kolemen, S.L. Allen, A.W. Hyatt, M.E. Fenstermacher, D.A. Humphreys, Vlad Soukhanovskii, M. A. Makowski, Ezekial A Unterberg, B.D. Bray, P. J. Vail, A.W. Leonard, Raffi Nazikian, T.W. Petrie, and C.J. Lasnier
Subjects: Physics, Nuclear and High Energy Physics, Tokamak, DIII-D, Divertor, Mechanics, Fusion power, Condensed Matter Physics, 01 natural sciences, Null (physics), 010305 fluids & plasmas, law.invention, Heat flux, Electromagnetic coil, law, 0103 physical sciences, Snowflake, 010306 general physics
Abstract: Simultaneous control of two proximate magnetic field nulls in the divertor region is demonstrated on DIII–D to enable plasma operations in an advanced magnetic configuration known as the snowflake divertor (SFD). The SFD is characterized by a second-order poloidal field null, created by merging two first-order nulls of the standard divertor configuration. The snowflake configuration has many magnetic properties, such as high poloidal flux expansion, large plasma-wetted area, and additional strike points, that are advantageous for divertor heat flux management in future fusion reactors. However, the magnetic configuration of the SFD is highly-sensitive to changes in currents within the plasma and external coils and therefore requires complex magnetic control. The first real-time snowflake detection and control system on DIII–D has been implemented in order to stabilize the configuration. The control algorithm calculates the position of the two nulls in real-time by locally-expanding the Grad–Shafranov equation in the divertor region. A linear relation between variations in the poloidal field coil currents and changes in the null locations is then analytically derived. This formulation allows for simultaneous control of multiple coils to achieve a desired SFD configuration. It is shown that the control enabled various snowflake configurations on DIII–D in scenarios such as the double-null advanced tokamak. The SFD resulted in a 2.5× reduction in the peak heat flux for many energy confinement times (2–3 s) without any adverse effects on core plasma performance.
Published: 2018

47. Scenario development during commissioning operations on the National Spherical Torus Experiment Upgrade

Author: M. Ono, Jonathan Menard, W. Guttenfelder, Filippo Scotti, Roger Raman, S.M. Kaye, S.P. Gerhardt, Michael Jaworski, D. Mueller, Nathaniel Ferraro, R.E. Bell, Mario Podesta, B.P. LeBlanc, Jinseop Park, D. J. Battaglia, S.A. Sabbagh, M. D. Boyer, Ahmed Diallo, John Berkery, Vlad Soukhanovskii, F. Bedoya, and Clayton E. Myers
Subjects: Physics, Nuclear and High Energy Physics, Project commissioning, business.industry, Spherical tokamak, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Upgrade, Development (topology), Real-time Control System, 0103 physical sciences, Aerospace engineering, 010306 general physics, business, National Spherical Torus Experiment
Published: 2018

48. Electron-density-sensitive Line Ratios of Fe xiii– xvi from Laboratory Sources Compared to CHIANTI

Author: Vlad Soukhanovskii, Peter Beiersdorfer, B.P. LeBlanc, Michael E. Weller, and Filippo Scotti
Subjects: Physics, Electron density, Spectrometer, Thomson scattering, Analytical chemistry, Astronomy and Astrophysics, Electron, Laser, 01 natural sciences, Spectral line, 010305 fluids & plasmas, law.invention, Space and Planetary Science, law, 0103 physical sciences, Spectral resolution, 010303 astronomy & astrophysics, Line (formation)
Abstract: We present electron-density-sensitive line ratios for Fe xiii– xvi measured in the spectral wavelength range of 200–440 A and an electron density range of (1–4) × 1013 cm−3. The results provide a test at the high-density limit of density-sensitive line ratios useful for astrophysical studies. The measurements were performed on the National Spherical Torus Experiment-Upgrade, where electron densities were measured independently by the laser Thomson scattering diagnostic. Spectra were collected with a flat-field grazing-incidence spectrometer, which provided a spectral resolution of up to 0.3 A, i.e., high resolution across the broad wavelength range. The response of the instrument was relatively calibrated using spectroscopic techniques in order to improve accuracy. The line ratios are compared to other laboratory sources and the latest version of CHIANTI (8.0.2), and an agreement within 30% is found.
Published: 2018

49. Developing physics basis for the snowflake divertor in the DIII-D tokamak

Author: W.H. Meyer, Vlad Soukhanovskii, S.L. Allen, T.H. Osborne, M. A. Makowski, C.J. Lasnier, R. J. Groebner, Dmitri Ryutov, T.W. Petrie, Adam McLean, A.W. Hyatt, M.E. Fenstermacher, J.G. Watkins, Egemen Kolemen, and A.W. Leonard
Subjects: Physics, Nuclear and High Energy Physics, Tokamak, DIII-D, Divertor, Energy transfer, Nuclear engineering, Plasma confinement, Magnetic confinement fusion, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, law.invention, law, Plasma instability, 0103 physical sciences, Snowflake, 010306 general physics
Published: 2018

50. Solenoid-Less Plasma Start-Up in NSTX Using Transient CHI

Author: M.G. Bell, R.J. Maqueda, Thomas Jarboe, David Gates, Masayoshi Nagata, Vlad Soukhanovskii, Masayuki Ono, Brian Nelson, B.P. LeBlanc, Lane Roquemore, S.A. Sabbagh, Roger Raman, Jonathan Menard, R.E. Bell, D. Mueller, and Rajesh Maingi
Subjects: Physics, Nuclear and High Energy Physics, Toroid, Tokamak, 020209 energy, Mechanical Engineering, Nuclear engineering, Magnetic confinement fusion, Solenoid, 02 engineering and technology, Plasma, 01 natural sciences, 010305 fluids & plasmas, law.invention, Inductance, Nuclear Energy and Engineering, Physics::Plasma Physics, law, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Transient (oscillation), Coaxial, Civil and Structural Engineering
Abstract: Experiments in NSTX have now unambiguously demonstrated the coupling of toroidal plasmas produced by the method of transient Coaxial Helicity Injection (CHI) to inductive sustainment and ramp-up of the toroidal current. The coupled discharges have ramped up to 700 kA and transitioned into H-mode with low inductance typical of the type of discharges needed for long-pulse operation, demonstrating the compatibility of the CHI startup method to conventional inductive operation used since the start of tokamak research. The method was first demonstrated on the smaller concept exploration device HIT-II at the University of Washington. These new results that were obtained on a machine built with mainly conventional components and on a size scale closer to a Component Test Facility, demonstrate that CHI is a viable solenoid-free plasma startup method for future STs and Tokamaks.
Published: 2009

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