Your search keyword '"Majeski, R."' showing total 22 results

1. An overview of recent physics results from NSTX

Author

Kaye, SM, Abrams, T, Ahn, J-W, Allain, JP, Andre, R, Andruczyk, D, Barchfeld, R, Battaglia, D, Bhattacharjee, A, Bedoya, F, Bell, RE, Belova, E, Berkery, J, Berry, L, Bertelli, N, Beiersdorfer, P, Bialek, J, Bilato, R, Boedo, J, Bonoli, P, Boozer, A, Bortolon, A, Boyer, MD, Boyle, D, Brennan, D, Breslau, J, Brooks, J, Buttery, R, Capece, A, Canik, J, Chang, CS, Crocker, N, Darrow, D, Davis, W, Delgado-Aparicio, L, Diallo, A, D'Ippolito, D, Domier, C, Ebrahimi, F, Ethier, S, Evans, T, Ferraro, N, Ferron, J, Finkenthal, M, Fonck, R, Fredrickson, E, Fu, GY, Gates, D, Gerhardt, S, Glasser, A, Gorelenkov, N, Gorelenkova, M, Goumiri, I, Gray, T, Green, D, Guttenfelder, W, Harvey, R, Hassanein, A, Heidbrink, W, Hirooka, Y, Hooper, EB, Hosea, J, Humphreys, D, Jaeger, EF, Jarboe, T, Jardin, S, Jaworski, MA, Kaita, R, Kessel, C, Kim, K, Koel, B, Kolemen, E, Kramer, G, Ku, S, Kubota, S, LaHaye, RJ, Lao, L, LeBlanc, BP, Levinton, F, Liu, D, Lore, J, Lucia, M, Luhmann, N, Maingi, R, Majeski, R, Mansfield, D, Maqueda, R, McKee, G, Medley, S, Meier, E, Menard, J, Mueller, D, Munsat, T, Muscatello, C, Myra, J, Nelson, B, Nichols, J, Ono, M, Osborne, T, and Park, J-K

Subjects

NSTX, spherical torus, overview, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Fluids & Plasmas

Abstract

The National Spherical Torus Experiment (NSTX) is currently being upgraded to operate at twice the toroidal field and plasma current (up to 1T and 2MA), with a second, more tangentially aimed neutral beam (NB) for current and rotation control, allowing for pulse lengths up to 5s. Recent NSTX physics analyses have addressed topics that will allow NSTX-Upgrade to achieve the research goals critical to a Fusion Nuclear Science Facility. These include producing stable, 100% non-inductive operation in high-performance plasmas, assessing plasma-material interface (PMI) solutions to handle the high heat loads expected in the next-step devices and exploring the unique spherical torus (ST) parameter regimes to advance predictive capability. Non-inductive operation and current profile control in NSTX-U will be facilitated by co-axial helicity injection (CHI) as well as radio frequency (RF) and NB heating. CHI studies using NIMROD indicate that the reconnection process is consistent with the 2D Sweet-Parker theory. Full-wave AORSA simulations show that RF power losses in the scrape-off layer (SOL) increase significantly for both NSTX and NSTX-U when the launched waves propagate in the SOL. Toroidal Alfvén eigenmode avalanches and higher frequency Alfvén eigenmodes can affect NB-driven current through energy loss and redistribution of fast ions. The inclusion of rotation and kinetic resonances, which depend on collisionality, is necessary for predicting experimental stability thresholds of fast growing ideal wall and resistive wall modes. Neutral beams and neoclassical toroidal viscosity generated from applied 3D fields can be used as actuators to produce rotation profiles optimized for global stability. DEGAS-2 has been used to study the dependence of gas penetration on SOL temperatures and densities for the MGI system being implemented on the Upgrade for disruption mitigation. PMI studies have focused on the effect of ELMs and 3D fields on plasma detachment and heat flux handling. Simulations indicate that snowflake and impurity seeded radiative divertors are candidates for heat flux mitigation in NSTX-U. Studies of lithium evaporation on graphite surfaces indicate that lithium increases oxygen surface concentrations on graphite, and deuterium-oxygen affinity, which increases deuterium pumping and reduces recycling. In situ and test-stand experiments of lithiated graphite and molybdenum indicate temperature-enhanced sputtering, although that test-stand studies also show the potential for heat flux reduction through lithium vapour shielding. Non-linear gyro kinetic simulations have indicated that ion transport can be enhanced by a shear-flow instability, and that non-local effects are necessary to explain the observed rapid changes in plasma turbulence. Predictive simulations have shown agreement between a microtearing-based reduced transport model and the measured electron temperatures in a microtearing unstable regime. Two Alfvén eigenmode-driven fast ion transport models have been developed and successfully benchmarked against NSTX data. Upgrade construction is moving on schedule with initial physics research operation of NSTX-U planned for mid-2015.

Published

2015

2. An overview of recent physics results from NSTX

Author

Kaye, SM, Abrams, T, Ahn, JW, Allain, JP, Andre, R, Andruczyk, D, Barchfeld, R, Battaglia, D, Bhattacharjee, A, Bedoya, F, Bell, RE, Belova, E, Berkery, J, Berry, L, Bertelli, N, Beiersdorfer, P, Bialek, J, Bilato, R, Boedo, J, Bonoli, P, Boozer, A, Bortolon, A, Boyer, MD, Boyle, D, Brennan, D, Breslau, J, Brooks, J, Buttery, R, Capece, A, Canik, J, Chang, CS, Crocker, N, Darrow, D, Davis, W, Delgado-Aparicio, L, Diallo, A, D'Ippolito, D, Domier, C, Ebrahimi, F, Ethier, S, Evans, T, Ferraro, N, Ferron, J, Finkenthal, M, Fonck, R, Fredrickson, E, Fu, GY, Gates, D, Gerhardt, S, Glasser, A, Gorelenkov, N, Gorelenkova, M, Goumiri, I, Gray, T, Green, D, Guttenfelder, W, Harvey, R, Hassanein, A, Heidbrink, W, Hirooka, Y, Hooper, EB, Hosea, J, Humphreys, D, Jaeger, EF, Jarboe, T, Jardin, S, Jaworski, MA, Kaita, R, Kessel, C, Kim, K, Koel, B, Kolemen, E, Kramer, G, Ku, S, Kubota, S, Lahaye, RJ, Lao, L, Leblanc, BP, Levinton, F, Liu, D, Lore, J, Lucia, M, Jr, NL, Maingi, R, Majeski, R, Mansfield, D, Maqueda, R, McKee, G, Medley, S, Meier, E, Menard, J, Mueller, D, Munsat, T, Muscatello, C, Myra, J, Nelson, B, Nichols, J, Ono, M, Osborne, T, and Park, JK

Subjects

NSTX, spherical torus, overview, Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

The National Spherical Torus Experiment (NSTX) is currently being upgraded to operate at twice the toroidal field and plasma current (up to 1T and 2MA), with a second, more tangentially aimed neutral beam (NB) for current and rotation control, allowing for pulse lengths up to 5s. Recent NSTX physics analyses have addressed topics that will allow NSTX-Upgrade to achieve the research goals critical to a Fusion Nuclear Science Facility. These include producing stable, 100% non-inductive operation in high-performance plasmas, assessing plasma-material interface (PMI) solutions to handle the high heat loads expected in the next-step devices and exploring the unique spherical torus (ST) parameter regimes to advance predictive capability. Non-inductive operation and current profile control in NSTX-U will be facilitated by co-axial helicity injection (CHI) as well as radio frequency (RF) and NB heating. CHI studies using NIMROD indicate that the reconnection process is consistent with the 2D Sweet-Parker theory. Full-wave AORSA simulations show that RF power losses in the scrape-off layer (SOL) increase significantly for both NSTX and NSTX-U when the launched waves propagate in the SOL. Toroidal Alfvén eigenmode avalanches and higher frequency Alfvén eigenmodes can affect NB-driven current through energy loss and redistribution of fast ions. The inclusion of rotation and kinetic resonances, which depend on collisionality, is necessary for predicting experimental stability thresholds of fast growing ideal wall and resistive wall modes. Neutral beams and neoclassical toroidal viscosity generated from applied 3D fields can be used as actuators to produce rotation profiles optimized for global stability. DEGAS-2 has been used to study the dependence of gas penetration on SOL temperatures and densities for the MGI system being implemented on the Upgrade for disruption mitigation. PMI studies have focused on the effect of ELMs and 3D fields on plasma detachment and heat flux handling. Simulations indicate that snowflake and impurity seeded radiative divertors are candidates for heat flux mitigation in NSTX-U. Studies of lithium evaporation on graphite surfaces indicate that lithium increases oxygen surface concentrations on graphite, and deuterium-oxygen affinity, which increases deuterium pumping and reduces recycling. In situ and test-stand experiments of lithiated graphite and molybdenum indicate temperature-enhanced sputtering, although that test-stand studies also show the potential for heat flux reduction through lithium vapour shielding. Non-linear gyro kinetic simulations have indicated that ion transport can be enhanced by a shear-flow instability, and that non-local effects are necessary to explain the observed rapid changes in plasma turbulence. Predictive simulations have shown agreement between a microtearing-based reduced transport model and the measured electron temperatures in a microtearing unstable regime. Two Alfvén eigenmode-driven fast ion transport models have been developed and successfully benchmarked against NSTX data. Upgrade construction is moving on schedule with initial physics research operation of NSTX-U planned for mid-2015.

Published

2015

3. Overview of physics results from the conclusive operation of the National Spherical Torus Experiment

Author

Sabbagh, SA, Ahn, J-W, Allain, J, Andre, R, Balbaky, A, Bastasz, R, Battaglia, D, Bell, M, Bell, R, Beiersdorfer, P, Belova, E, Berkery, J, Betti, R, Bialek, J, Bigelow, T, Bitter, M, Boedo, J, Bonoli, P, Boozer, A, Bortolon, A, Boyle, D, Brennan, D, Breslau, J, Buttery, R, Canik, J, Caravelli, G, Chang, C, Crocker, N, Darrow, D, Davis, B, Delgado-Aparicio, L, Diallo, A, Ding, S, D'Ippolito, D, Domier, C, Dorland, W, Ethier, S, Evans, T, Ferron, J, Finkenthal, M, Foley, J, Fonck, R, Frazin, R, Fredrickson, E, Fu, G, Gates, D, Gerhardt, S, Glasser, A, Gorelenkov, N, Gray, T, Guo, Y, Guttenfelder, W, Hahm, T, Harvey, R, Hassanein, A, Heidbrink, W, Hill, K, Hirooka, Y, Hooper, EB, Hosea, J, Humphreys, D, Indireshkumar, K, Jaeger, F, Jarboe, T, Jardin, S, Jaworski, M, Kaita, R, Kallman, J, Katsuro-Hopkins, O, Kaye, S, Kessel, C, Kim, J, Kolemen, E, Kramer, G, Krasheninnikov, S, Kubota, S, Kugel, H, La Haye, RJ, Lao, L, LeBlanc, B, Lee, W, Lee, K, Leuer, J, Levinton, F, Liang, Y, Liu, D, Lore, J, Luhmann, N, Maingi, R, Majeski, R, Manickam, J, Mansfield, D, Maqueda, R, Mazzucato, E, McLean, A, McCune, D, McGeehan, B, McKee, G, Medley, S, and Meier, E

Subjects

Atomic, Molecular, Nuclear, Particle and Plasma Physics, Fluids & Plasmas

Abstract

Research on the National Spherical Torus Experiment, NSTX, targets physics understanding needed for extrapolation to a steady-state ST Fusion Nuclear Science Facility, pilot plant, or DEMO. The unique ST operational space is leveraged to test physics theories for next-step tokamak operation, including ITER. Present research also examines implications for the coming device upgrade, NSTX-U. An energy confinement time, τE, scaling unified for varied wall conditions exhibits a strong improvement of BTτE with decreased electron collisionality, accentuated by lithium (Li) wall conditioning. This result is consistent with nonlinear microtearing simulations that match the experimental electron diffusivity quantitatively and predict reduced electron heat transport at lower collisionality. Beam-emission spectroscopy measurements in the steep gradient region of the pedestal indicate the poloidal correlation length of turbulence of about ten ion gyroradii increases at higher electron density gradient and lower Ti gradient, consistent with turbulence caused by trapped electron instabilities. Density fluctuations in the pedestal top region indicate ion-scale microturbulence compatible with ion temperature gradient and/or kinetic ballooning mode instabilities. Plasma characteristics change nearly continuously with increasing Li evaporation and edge localized modes (ELMs) stabilize due to edge density gradient alteration. Global mode stability studies show stabilizing resonant kinetic effects are enhanced at lower collisionality, but in stark contrast have almost no dependence on collisionality when the plasma is off-resonance. Combined resistive wall mode radial and poloidal field sensor feedback was used to control n = 1 perturbations and improve stability. The disruption probability due to unstable resistive wall modes (RWMs) was surprisingly reduced at very high βN/li > 10 consistent with low frequency magnetohydrodynamic spectroscopy measurements of mode stability. Greater instability seen at intermediate βN is consistent with decreased kinetic RWM stabilization. A model-based RWM state-space controller produced long-pulse discharges exceeding βN = 6.4 and βN/li = 13. Precursor analysis shows 96.3% of disruptions can be predicted with 10 ms warning and a false positive rate of only 2.8%. Disruption halo currents rotate toroidally and can have significant toroidal asymmetry. Global kinks cause measured fast ion redistribution, with full-orbit calculations showing redistribution from the core outward and towards V∥/V = 1 where destabilizing compressional Alfvén eigenmode resonances are expected. Applied 3D fields altered global Alfvén eigenmode characteristics. High-harmonic fast-wave (HHFW) power couples to field lines across the entire width of the scrape-off layer, showing the importance of the inclusion of this phenomenon in designing future RF systems. The snowflake divertor configuration enhanced by radiative detachment showed large reductions in both steady-state and ELM heat fluxes (ELMing peak values down from 19 MW m-2 to less than 1.5 MW m-2). Toroidal asymmetry of heat deposition was observed during ELMs or by 3D fields. The heating power required for accessing H-mode decreased by 30% as the triangularity was decreased by moving the X-point to larger radius, consistent with calculations of the dependence of E × B shear in the edge region on ion heat flux and X-point radius. Co-axial helicity injection reduced the inductive start-up flux, with plasmas ramped to 1 MA requiring 35% less inductive flux. Non-inductive current fraction (NICF) up to 65% is reached experimentally with neutral beam injection at plasma current Ip = 0.7 MA and between 70-100% with HHFW application at Ip = 0.3 MA. NSTX-U scenario development calculations project 100% NICF for a large range of 0.6 < Ip (MA) < 1.35. © 2013 IAEA, Vienna.

Published

2013

4. Overview of physics results from the conclusive operation of the National Spherical Torus Experiment

Author

Sabbagh, SA, Ahn, JW, Allain, J, Andre, R, Balbaky, A, Bastasz, R, Battaglia, D, Bell, M, Bell, R, Beiersdorfer, P, Belova, E, Berkery, J, Betti, R, Bialek, J, Bigelow, T, Bitter, M, Boedo, J, Bonoli, P, Boozer, A, Bortolon, A, Boyle, D, Brennan, D, Breslau, J, Buttery, R, Canik, J, Caravelli, G, Chang, C, Crocker, N, Darrow, D, Davis, B, Delgado-Aparicio, L, Diallo, A, Ding, S, D'Ippolito, D, Domier, C, Dorland, W, Ethier, S, Evans, T, Ferron, J, Finkenthal, M, Foley, J, Fonck, R, Frazin, R, Fredrickson, E, Fu, G, Gates, D, Gerhardt, S, Glasser, A, Gorelenkov, N, Gray, T, Guo, Y, Guttenfelder, W, Hahm, T, Harvey, R, Hassanein, A, Heidbrink, W, Hill, K, Hirooka, Y, Hooper, EB, Hosea, J, Humphreys, D, Indireshkumar, K, Jaeger, F, Jarboe, T, Jardin, S, Jaworski, M, Kaita, R, Kallman, J, Katsuro-Hopkins, O, Kaye, S, Kessel, C, Kim, J, Kolemen, E, Kramer, G, Krasheninnikov, S, Kubota, S, Kugel, H, La Haye, RJ, Lao, L, Leblanc, B, Lee, W, Lee, K, Leuer, J, Levinton, F, Liang, Y, Liu, D, Lore, J, Luhmann, N, Maingi, R, Majeski, R, Manickam, J, Mansfield, D, Maqueda, R, Mazzucato, E, McLean, A, McCune, D, McGeehan, B, McKee, G, Medley, S, and Meier, E

Subjects

Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

Research on the National Spherical Torus Experiment, NSTX, targets physics understanding needed for extrapolation to a steady-state ST Fusion Nuclear Science Facility, pilot plant, or DEMO. The unique ST operational space is leveraged to test physics theories for next-step tokamak operation, including ITER. Present research also examines implications for the coming device upgrade, NSTX-U. An energy confinement time, τE, scaling unified for varied wall conditions exhibits a strong improvement of BTτE with decreased electron collisionality, accentuated by lithium (Li) wall conditioning. This result is consistent with nonlinear microtearing simulations that match the experimental electron diffusivity quantitatively and predict reduced electron heat transport at lower collisionality. Beam-emission spectroscopy measurements in the steep gradient region of the pedestal indicate the poloidal correlation length of turbulence of about ten ion gyroradii increases at higher electron density gradient and lower Ti gradient, consistent with turbulence caused by trapped electron instabilities. Density fluctuations in the pedestal top region indicate ion-scale microturbulence compatible with ion temperature gradient and/or kinetic ballooning mode instabilities. Plasma characteristics change nearly continuously with increasing Li evaporation and edge localized modes (ELMs) stabilize due to edge density gradient alteration. Global mode stability studies show stabilizing resonant kinetic effects are enhanced at lower collisionality, but in stark contrast have almost no dependence on collisionality when the plasma is off-resonance. Combined resistive wall mode radial and poloidal field sensor feedback was used to control n = 1 perturbations and improve stability. The disruption probability due to unstable resistive wall modes (RWMs) was surprisingly reduced at very high βN/li > 10 consistent with low frequency magnetohydrodynamic spectroscopy measurements of mode stability. Greater instability seen at intermediate βN is consistent with decreased kinetic RWM stabilization. A model-based RWM state-space controller produced long-pulse discharges exceeding βN = 6.4 and βN/li = 13. Precursor analysis shows 96.3% of disruptions can be predicted with 10 ms warning and a false positive rate of only 2.8%. Disruption halo currents rotate toroidally and can have significant toroidal asymmetry. Global kinks cause measured fast ion redistribution, with full-orbit calculations showing redistribution from the core outward and towards V∥/V = 1 where destabilizing compressional Alfvén eigenmode resonances are expected. Applied 3D fields altered global Alfvén eigenmode characteristics. High-harmonic fast-wave (HHFW) power couples to field lines across the entire width of the scrape-off layer, showing the importance of the inclusion of this phenomenon in designing future RF systems. The snowflake divertor configuration enhanced by radiative detachment showed large reductions in both steady-state and ELM heat fluxes (ELMing peak values down from 19 MW m-2 to less than 1.5 MW m-2). Toroidal asymmetry of heat deposition was observed during ELMs or by 3D fields. The heating power required for accessing H-mode decreased by 30% as the triangularity was decreased by moving the X-point to larger radius, consistent with calculations of the dependence of E × B shear in the edge region on ion heat flux and X-point radius. Co-axial helicity injection reduced the inductive start-up flux, with plasmas ramped to 1 MA requiring 35% less inductive flux. Non-inductive current fraction (NICF) up to 65% is reached experimentally with neutral beam injection at plasma current Ip = 0.7 MA and between 70-100% with HHFW application at Ip = 0.3 MA. NSTX-U scenario development calculations project 100% NICF for a large range of 0.6 < Ip (MA) < 1.35. © 2013 IAEA, Vienna.

Published

2013

5. Overview of physics results from NSTX

Author

Raman, R, Ahn, J-W, Allain, JP, Andre, R, Bastasz, R, Battaglia, D, Beiersdorfer, P, Bell, M, Bell, R, Belova, E, Berkery, J, Betti, R, Bialek, J, Bigelow, T, Bitter, M, Boedo, J, Bonoli, P, Boozer, A, Bortolon, A, Brennan, D, Breslau, J, Buttery, R, Canik, J, Caravelli, G, Chang, C, Crocker, NA, Darrow, D, Davis, W, Delgado-Aparicio, L, Diallo, A, Ding, S, D'Ippolito, D, Domier, C, Dorland, W, Ethier, S, Evans, T, Ferron, J, Finkenthal, M, Foley, J, Fonck, R, Frazin, R, Fredrickson, E, Fu, G, Gates, D, Gerhardt, S, Glasser, A, Gorelenkov, N, Gray, T, Guo, Y, Guttenfelder, W, Hahm, T, Harvey, R, Hassanein, A, Heidbrink, W, Hill, K, Hirooka, Y, Hooper, EB, Hosea, J, Hu, B, Humphreys, D, Indireshkumar, K, Jaeger, F, Jarboe, T, Jardin, S, Jaworski, M, Kaita, R, Kallman, J, Katsuro-Hopkins, O, Kaye, S, Kessel, C, Kim, J, Kolemen, E, Krasheninnikov, S, Kubota, S, Kugel, H, La Haye, R, Lao, L, LeBlanc, B, Lee, W, Lee, K, Leuer, J, Levinton, F, Liang, Y, Liu, D, Luhmann, N, Maingi, R, Majeski, R, Manickam, J, Mansfield, D, Maqueda, R, Mazzucato, E, McLean, A, McCune, D, McGeehan, B, McKee, G, Medley, S, Menard, J, Menon, M, Meyer, H, and Mikkelsen, D

Subjects

Atomic, Molecular, Nuclear, Particle and Plasma Physics, Fluids & Plasmas

Abstract

In the last two experimental campaigns, the low aspect ratio NSTX has explored physics issues critical to both toroidal confinement physics and ITER. Experiments have made extensive use of lithium coatings for wall conditioning, correction of non-axisymmetric field errors and control of n = 1 resistive wall modes (RWMs) to produce high-performance neutral-beam heated discharges extending to 1.7 s in duration with non-inductive current fractions up to 0.7. The RWM control coils have been used to trigger repetitive ELMs with high reliability, and they have also contributed to an improved understanding of both neoclassical tearing mode and RWM stabilization physics, including the interplay between rotation and kinetic effects on stability. High harmonic fast wave (HHFW) heating has produced plasmas with central electron temperatures exceeding 6 keV. The HHFW heating was used to show that there was a 20-40% higher power threshold for the L-H transition for helium than for deuterium plasmas. A new diagnostic showed a depletion of the fast-ion density profile over a broad spatial region as a result of toroidicity-induced Alfvén eigenmodes (TAEs) and energetic-particle modes (EPMs) bursts. In addition, it was observed that other modes (e.g. global Alfvén eigenmodes) can trigger TAE and EPM bursts, suggesting that fast ions are redistributed by high-frequency AEs. The momentum pinch velocity determined by a perturbative technique decreased as the collisionality was reduced, although the pinch to diffusion ratio, Vpinch/χ, remained approximately constant. The mechanisms of deuterium retention by graphite and lithium-coated graphite plasma-facing components have been investigated. To reduce divertor heat flux, a novel divertor configuration, the 'snowflake' divertor, was tested in NSTX and many beneficial aspects were found. A reduction in the required central solenoid flux has been realized in NSTX when discharges initiated by coaxial helicity injection were ramped in current using induction. The resulting plasmas have characteristics needed to meet the objectives of the non-inductive start-up and ramp-up program of NSTX. © 2011 IAEA, Vienna.

Published

2011

6. Overview of physics results from NSTX

Author

Raman, R, Ahn, JW, Allain, JP, Andre, R, Bastasz, R, Battaglia, D, Beiersdorfer, P, Bell, M, Bell, R, Belova, E, Berkery, J, Betti, R, Bialek, J, Bigelow, T, Bitter, M, Boedo, J, Bonoli, P, Boozer, A, Bortolon, A, Brennan, D, Breslau, J, Buttery, R, Canik, J, Caravelli, G, Chang, C, Crocker, NA, Darrow, D, Davis, W, Delgado-Aparicio, L, Diallo, A, Ding, S, D'Ippolito, D, Domier, C, Dorland, W, Ethier, S, Evans, T, Ferron, J, Finkenthal, M, Foley, J, Fonck, R, Frazin, R, Fredrickson, E, Fu, G, Gates, D, Gerhardt, S, Glasser, A, Gorelenkov, N, Gray, T, Guo, Y, Guttenfelder, W, Hahm, T, Harvey, R, Hassanein, A, Heidbrink, W, Hill, K, Hirooka, Y, Hooper, EB, Hosea, J, Hu, B, Humphreys, D, Indireshkumar, K, Jaeger, F, Jarboe, T, Jardin, S, Jaworski, M, Kaita, R, Kallman, J, Katsuro-Hopkins, O, Kaye, S, Kessel, C, Kim, J, Kolemen, E, Krasheninnikov, S, Kubota, S, Kugel, H, La Haye, R, Lao, L, Leblanc, B, Lee, W, Lee, K, Leuer, J, Levinton, F, Liang, Y, Liu, D, Luhmann, N, Maingi, R, Majeski, R, Manickam, J, Mansfield, D, Maqueda, R, Mazzucato, E, McLean, A, McCune, D, McGeehan, B, McKee, G, Medley, S, Menard, J, Menon, M, Meyer, H, and Mikkelsen, D

Subjects

Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

In the last two experimental campaigns, the low aspect ratio NSTX has explored physics issues critical to both toroidal confinement physics and ITER. Experiments have made extensive use of lithium coatings for wall conditioning, correction of non-axisymmetric field errors and control of n = 1 resistive wall modes (RWMs) to produce high-performance neutral-beam heated discharges extending to 1.7 s in duration with non-inductive current fractions up to 0.7. The RWM control coils have been used to trigger repetitive ELMs with high reliability, and they have also contributed to an improved understanding of both neoclassical tearing mode and RWM stabilization physics, including the interplay between rotation and kinetic effects on stability. High harmonic fast wave (HHFW) heating has produced plasmas with central electron temperatures exceeding 6 keV. The HHFW heating was used to show that there was a 20-40% higher power threshold for the L-H transition for helium than for deuterium plasmas. A new diagnostic showed a depletion of the fast-ion density profile over a broad spatial region as a result of toroidicity-induced Alfvén eigenmodes (TAEs) and energetic-particle modes (EPMs) bursts. In addition, it was observed that other modes (e.g. global Alfvén eigenmodes) can trigger TAE and EPM bursts, suggesting that fast ions are redistributed by high-frequency AEs. The momentum pinch velocity determined by a perturbative technique decreased as the collisionality was reduced, although the pinch to diffusion ratio, Vpinch/χ, remained approximately constant. The mechanisms of deuterium retention by graphite and lithium-coated graphite plasma-facing components have been investigated. To reduce divertor heat flux, a novel divertor configuration, the 'snowflake' divertor, was tested in NSTX and many beneficial aspects were found. A reduction in the required central solenoid flux has been realized in NSTX when discharges initiated by coaxial helicity injection were ramped in current using induction. The resulting plasmas have characteristics needed to meet the objectives of the non-inductive start-up and ramp-up program of NSTX. © 2011 IAEA, Vienna.

Published

2011

7. Overview of results from the National Spherical Torus Experiment (NSTX)

Author

Gates, DA, Ahn, J, Allain, J, Andre, R, Bastasz, R, Bell, M, Bell, R, Belova, E, Berkery, J, Betti, R, Bialek, J, Biewer, T, Bigelow, T, Bitter, M, Boedo, J, Bonoli, P, Boozer, A, Brennan, D, Breslau, J, Brower, D, Bush, C, Canik, J, Caravelli, G, Carter, M, Caughman, J, Chang, C, Choe, W, Crocker, N, Darrow, D, Delgado-Aparicio, L, Diem, S, D'Ippolito, D, Domier, C, Dorland, W, Efthimion, P, Ejiri, A, Ershov, N, Evans, T, Feibush, E, Fenstermacher, M, Ferron, J, Finkenthal, M, Foley, J, Frazin, R, Fredrickson, E, Fu, G, Funaba, H, Gerhardt, S, Glasser, A, Gorelenkov, N, Grisham, L, Hahm, T, Harvey, R, Hassanein, A, Heidbrink, W, Hill, K, Hillesheim, J, Hillis, D, Hirooka, Y, Hosea, J, Hu, B, Humphreys, D, Idehara, T, Indireshkumar, K, Ishida, A, Jaeger, F, Jarboe, T, Jardin, S, Jaworski, M, Ji, H, Jung, H, Kaita, R, Kallman, J, Katsuro-Hopkins, O, Kawahata, K, Kawamori, E, Kaye, S, Kessel, C, Kim, J, Kimura, H, Kolemen, E, Krasheninnikov, S, Krstic, P, Ku, S, Kubota, S, Kugel, H, La Haye, R, Lao, L, LeBlanc, B, Lee, W, Lee, K, Leuer, J, Levinton, F, Liang, Y, Liu, D, Luhmann, N, Maingi, R, Majeski, R, Manickam, J, and Mansfield, D

Subjects

Atomic, Molecular, Nuclear, Particle and Plasma Physics, Fluids & Plasmas

Abstract

The mission of the National Spherical Torus Experiment (NSTX) is the demonstration of the physics basis required to extrapolate to the next steps for the spherical torus (ST), such as a plasma facing component test facility (NHTX) or an ST based component test facility (ST-CTF), and to support ITER. Key issues for the ST are transport, and steady state high β operation. To better understand electron transport, a new high-k scattering diagnostic was used extensively to investigate electron gyro-scale fluctuations with varying electron temperature gradient scale length. Results from n = 3 braking studies are consistent with the flow shear dependence of ion transport. New results from electron Bernstein wave emission measurements from plasmas with lithium wall coating applied indicate transmission efficiencies near 70% in H-mode as a result of reduced collisionality. Improved coupling of high harmonic fast-waves has been achieved by reducing the edge density relative to the critical density for surface wave coupling. In order to achieve high bootstrap current fraction, future ST designs envision running at very high elongation. Plasmas have been maintained on NSTX at very low internal inductance li ∼ 0.4 with strong shaping (κ ∼ 2.7, δ ∼ 0.8) with βN approaching the with-wall β-limit for several energy confinement times. By operating at lower collisionality in this regime, NSTX has achieved record non-inductive current drive fraction fNI ∼ 71%. Instabilities driven by super-Alfvénic ions will be an important issue for all burning plasmas, including ITER. Fast ions from NBI on NSTX are super-Alfvénic. Linear toroidal Alfvén eigenmode thresholds and appreciable fast ion loss during multi-mode bursts are measured and these results are compared with theory. The impact of n > 1 error fields on stability is an important result for ITER. Resistive wall mode/resonant field amplification feedback combined with n = 3 error field control was used on NSTX to maintain plasma rotation with β above the no-wall limit. Other highlights are results of lithium coating experiments, momentum confinement studies, scrape-off layer width scaling, demonstration of divertor heat load mitigation in strongly shaped plasmas and coupling of coaxial helicity injection plasmas to ohmic heating ramp-up. These results advance the ST towards next step fusion energy devices such as NHTX and ST-CTF. © 2009 IAEA, Vienna.

Published

2009

8. Overview of results from the national spherical torus experiment (NSTX)

Author

Gates, DA, Ahn, J, Allain, J, Andre, R, Bastasz, R, Bell, M, Bell, R, Belova, E, Berkery, J, Betti, R, Bialek, J, Biewer, T, Bigelow, T, Bitter, M, Boedo, J, Bonoli, P, Boozer, A, Brennan, D, Breslau, J, Brower, D, Bush, C, Canik, J, Caravelli, G, Carter, M, Caughman, J, Chang, C, Choe, W, Crocker, N, Darrow, D, Delgado-Aparicio, L, Diem, S, D'Ippolito, D, Domier, C, Dorland, W, Efthimion, P, Ejiri, A, Ershov, N, Evans, T, Feibush, E, Fenstermacher, M, Ferron, J, Finkenthal, M, Foley, J, Frazin, R, Fredrickson, E, Fu, G, Funaba, H, Gerhardt, S, Glasser, A, Gorelenkov, N, Grisham, L, Hahm, T, Harvey, R, Hassanein, A, Heidbrink, W, Hill, K, Hillesheim, J, Hillis, D, Hirooka, Y, Hosea, J, Hu, B, Humphreys, D, Idehara, T, Indireshkumar, K, Ishida, A, Jaeger, F, Jarboe, T, Jardin, S, Jaworski, M, Ji, H, Jung, H, Kaita, R, Kallman, J, Katsuro-Hopkins, O, Kawahata, K, Kawamori, E, Kaye, S, Kessel, C, Kim, J, Kimura, H, Kolemen, E, Krasheninnikov, S, Krstic, P, Ku, S, Kubota, S, Kugel, H, La Haye, R, Lao, L, Leblanc, B, Lee, W, Lee, K, Leuer, J, Levinton, F, Liang, Y, Liu, D, Luhmann, N, Maingi, R, Majeski, R, Manickam, J, and Mansfield, D

Subjects

Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

The mission of the National Spherical Torus Experiment (NSTX) is the demonstration of the physics basis required to extrapolate to the next steps for the spherical torus (ST), such as a plasma facing component test facility (NHTX) or an ST based component test facility (ST-CTF), and to support ITER. Key issues for the ST are transport, and steady state high β operation. To better understand electron transport, a new high-k scattering diagnostic was used extensively to investigate electron gyro-scale fluctuations with varying electron temperature gradient scale length. Results from n = 3 braking studies are consistent with the flow shear dependence of ion transport. New results from electron Bernstein wave emission measurements from plasmas with lithium wall coating applied indicate transmission efficiencies near 70% in H-mode as a result of reduced collisionality. Improved coupling of high harmonic fast-waves has been achieved by reducing the edge density relative to the critical density for surface wave coupling. In order to achieve high bootstrap current fraction, future ST designs envision running at very high elongation. Plasmas have been maintained on NSTX at very low internal inductance li ∼ 0.4 with strong shaping (κ ∼ 2.7, δ ∼ 0.8) with βN approaching the with-wall β-limit for several energy confinement times. By operating at lower collisionality in this regime, NSTX has achieved record non-inductive current drive fraction fNI ∼ 71%. Instabilities driven by super-Alfvénic ions will be an important issue for all burning plasmas, including ITER. Fast ions from NBI on NSTX are super-Alfvénic. Linear toroidal Alfvén eigenmode thresholds and appreciable fast ion loss during multi-mode bursts are measured and these results are compared with theory. The impact of n > 1 error fields on stability is an important result for ITER. Resistive wall mode/resonant field amplification feedback combined with n = 3 error field control was used on NSTX to maintain plasma rotation with β above the no-wall limit. Other highlights are results of lithium coating experiments, momentum confinement studies, scrape-off layer width scaling, demonstration of divertor heat load mitigation in strongly shaped plasmas and coupling of coaxial helicity injection plasmas to ohmic heating ramp-up. These results advance the ST towards next step fusion energy devices such as NHTX and ST-CTF. © 2009 IAEA, Vienna.

Published

2009

9. Progress towards high-performance, steady-state spherical torus

Author

Ono, M, Bell, MG, Bell, RE, Bigelow, T, Bitter, M, Blanchard, W, Boedo, J, Bourdelle, C, Bush, C, Choe, W, Chrzanowski, J, Darrow, DS, Diem, SJ, Doerner, R, Efthimion, PC, Ferron, JR, Fonck, RJ, Fredrickson, ED, Garstka, GD, Gates, DA, Gray, T, Grisham, LR, Heidbrink, W, Hill, KW, Hoffman, D, Jarboe, TR, Johnson, DW, Kaita, R, Kaye, SM, Kessel, C, Kim, JH, Kissick, MW, Kubota, S, Kugel, HW, LeBlanc, BP, Lee, K, Lee, SG, Lewicki, BT, Luckhardt, S, Maingi, R, Majeski, R, Manickam, J, Maqueda, R, Mau, TK, Mazzucato, E, Medley, SS, Menard, J, Mueller, D, Nelson, BA, Neumeyer, C, Nishino, N, Ostrander, CN, Pacella, D, Paoletti, F, Park, HK, Park, W, Paul, SF, Peng, Y-KM, Phillips, CK, Pinsker, R, Probert, PH, Ramakrishnan, S, Raman, R, Redi, M, Roquemore, AL, Rosenberg, A, Ryan, PM, Sabbagh, SA, Schaffer, M, Schooff, RJ, Seraydarian, R, Skinner, CH, Sontag, AC, Soukhanovskii, V, Spaleta, J, Stevenson, T, Stutman, D, Swain, DW, Synakowski, E, Takase, Y, Tang, X, Taylor, G, Timberlake, J, Tritz, KL, Unterberg, EA, Von Halle, A, Wilgen, J, Williams, M, Wilson, JR, Xu, X, Zweben, SJ, Akers, R, Barry, RE, Beiersdorfer, P, Bialek, JM, Blagojevic, B, Bonoli, PT, Carter, MD, Davis, W, and Deng, B

Subjects

Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Fluids & Plasmas

Abstract

Research on the spherical torus (or spherical tokamak) (ST) is being pursued to explore the scientific benefits of modifying the field line structue fro that in more moderate aspect ratio devices. The ST experiments are being conducted in various US research facilities. 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.

Published

2003

10. The national spherical torus experiment (NSTX) research programme and progress towards high beta, long pulse operating scenarios

Author

Synakowski, EJ, Bell, MG, Bell, RE, Bigelow, T, Bitter, M, Blanchard, W, Boedo, J, Bourdelle, C, Bush, C, Darrow, DS, Efthimion, PC, Fredrickson, ED, Gates, DA, Gilmore, M, Grisham, LR, Hosea, JC, Johnson, DW, Kaita, R, Kaye, SM, Kubota, S, Kugel, HW, LeBlanc, BP, Lee, K, Maingi, R, Manickam, J, Maqueda, R, Mazzucato, E, Medley, SS, Menard, J, Mueller, D, Nelson, BA, Neumeyer, C, Ono, M, Paoletti, F, Park, HK, Paul, SF, Peng, Y-KM, Phillips, CK, Ramakrishnan, S, Raman, R, Roquemore, AL, Rosenberg, A, Ryan, PM, Sabbagh, SA, Skinner, CH, Soukhanovskii, V, Stevenson, T, Stutman, D, Swain, DW, Taylor, G, Von Halle, A, Wilgen, J, Williams, M, Wilson, JR, Zweben, SJ, Akers, R, Barry, RE, Beiersdorfer, P, Bialek, JM, Blagojevic, B, Bonoli, PT, Budny, R, Carter, MD, Chang, CS, Chrzanowski, J, Davis, W, Deng, B, Doyle, EJ, Dudek, L, Egedal, J, Ellis, R, Ferron, JR, Finkenthal, M, Foley, J, Fredd, E, Glasser, A, Gibney, T, Goldston, RJ, Harvey, R, Hatcher, RE, Hawryluk, RJ, Heidbrink, W, Hill, KW, Houlberg, W, Jarboe, TR, Jardin, SC, Ji, H, Kalish, M, Lawrance, J, Lao, LL, Lee, KC, Levinton, FM, Luhmann, NC, Majeski, R, Marsala, R, Mastravito, D, Mau, TK, McCormack, B, Menon, MM, and Mitarai, O

Subjects

Atomic, Molecular, Nuclear, Particle and Plasma Physics, Fluids & Plasmas

Abstract

A major research goal of the national spherical torus experiment is establishing long-pulse, high beta, high confinement operation and its physics basis. This research has been enabled by facility capabilities developed during 2001 and 2002, including neutral beam (up to 7 MW) and high harmonic fast wave (HHFW) heating (up to 6 MW), toroidal fields up to 6 kG, plasma currents up to 1.5 MA, flexible shape control, and wall preparation techniques. These capabilities have enabled the generation of plasmas with βT ≡ /(BT02/2μ0) of up to 35%. Normalized beta values often exceed the no-wall limit, and studies suggest that passive wall mode stabilization enables this for H mode plasmas with broad pressure profiles. The viability of long, high bootstrap current fraction operations has been established for ELMing H mode plasmas with toroidal beta values in excess of 15% and sustained for several current relaxation times. Improvements in wall conditioning and fuelling are likely contributing to a reduction in H mode power thresholds. Electron thermal conduction is the dominant thermal loss channel is auxiliary heated plasmas examined thus far. HHFW effectively heats electrons, and its acceleration of fast beam ions has been observed. Evidence for HHFW current drive is obtained by comparison of the loop voltage evolution in plasmas with matched density and temperature profiles but varying phases of launched HHFW waves. Studies of emissions from electron Bernstein waves indicate a density scale length dependence of their transmission across the upper hybrid resonance near the plasma edge that is consistent with theoretical predictions. A peak heat flux to the divertor targets of 10 MW m-2 has been measured in the H mode, with large asymmetries being observed in the power deposition between the inner and outer strike points. Non-inductive plasma startup studies have focused on coaxial helicity injection. With this technique, toroidal currents up to 400 kA have been driven, and studies to assess flux closure and coupling to other current drive techniques have begun.

Published

2003

11. The national spherical torus experiment (NSTX) research programme and progress towards high beta, long pulse operating scenarios

Author

Synakowski, EJ, Bell, MG, Bell, RE, Bigelow, T, Bitter, M, Blanchard, W, Boedo, J, Bourdelle, C, Bush, C, Darrow, DS, Efthimion, PC, Fredrickson, ED, Gates, DA, Gilmore, M, Grisham, LR, Hosea, JC, Johnson, DW, Kaita, R, Kaye, SM, Kubota, S, Kugel, HW, LeBlanc, BP, Lee, K, Maingi, R, Manickam, J, Maqueda, R, Mazzucato, E, Medley, SS, Menard, J, Mueller, D, Nelson, BA, Neumeyer, C, Ono, M, Paoletti, F, Park, HK, Paul, SF, Peng, YKM, Phillips, CK, Ramakrishnan, S, Raman, R, Roquemore, AL, Rosenberg, A, Ryan, PM, Sabbagh, SA, Skinner, CH, Soukhanovskii, V, Stevenson, T, Stutman, D, Swain, DW, Taylor, G, von Halle, A, Wilgen, J, Williams, M, Wilson, JR, Zweben, SJ, Akers, R, Barry, RE, Beiersdorfer, P, Bialek, JM, Blagojevic, B, Bonoli, PT, Budny, R, Carter, MD, Chang, CS, Chrzanowski, J, Davis, W, Deng, B, Doyle, EJ, Dudek, L, Egedal, J, Ellis, R, Ferron, JR, Finkenthal, M, Foley, J, Fredd, E, Glasser, A, Gibney, T, Goldston, RJ, Harvey, R, Hatcher, RE, Hawryluk, RJ, Heidbrink, W, Hill, KW, Houlberg, W, Jarboe, TR, Jardin, SC, Ji, H, Kalish, M, Lawrance, J, Lao, LL, Lee, KC, Levinton, FM, Luhmann, NC, Majeski, R, Marsala, R, Mastravito, D, Mau, TK, McCormack, B, Menon, MM, and Mitarai, O

Subjects

Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

A major research goal of the national spherical torus experiment is establishing long-pulse, high beta, high confinement operation and its physics basis. This research has been enabled by facility capabilities developed during 2001 and 2002, including neutral beam (up to 7 MW) and high harmonic fast wave (HHFW) heating (up to 6 MW), toroidal fields up to 6 kG, plasma currents up to 1.5 MA, flexible shape control, and wall preparation techniques. These capabilities have enabled the generation of plasmas with βT ≡ /(BT02/2μ0) of up to 35%. Normalized beta values often exceed the no-wall limit, and studies suggest that passive wall mode stabilization enables this for H mode plasmas with broad pressure profiles. The viability of long, high bootstrap current fraction operations has been established for ELMing H mode plasmas with toroidal beta values in excess of 15% and sustained for several current relaxation times. Improvements in wall conditioning and fuelling are likely contributing to a reduction in H mode power thresholds. Electron thermal conduction is the dominant thermal loss channel is auxiliary heated plasmas examined thus far. HHFW effectively heats electrons, and its acceleration of fast beam ions has been observed. Evidence for HHFW current drive is obtained by comparison of the loop voltage evolution in plasmas with matched density and temperature profiles but varying phases of launched HHFW waves. Studies of emissions from electron Bernstein waves indicate a density scale length dependence of their transmission across the upper hybrid resonance near the plasma edge that is consistent with theoretical predictions. A peak heat flux to the divertor targets of 10 MW m-2 has been measured in the H mode, with large asymmetries being observed in the power deposition between the inner and outer strike points. Non-inductive plasma startup studies have focused on coaxial helicity injection. With this technique, toroidal currents up to 400 kA have been driven, and studies to assess flux closure and coupling to other current drive techniques have begun.

Published

2003

12. Progress towards high-performance, steady-state spherical torus

Author

Ono, M, Bell, MG, Bell, RE, Bigelow, T, Bitter, M, Blanchard, W, Boedo, J, Bourdelle, C, Bush, C, Choe, W, Chrzanowski, J, Darrow, DS, Diem, SJ, Doerner, R, Efthimion, PC, Ferron, JR, Fonck, RJ, Fredrickson, ED, Garstka, GD, Gates, DA, Gray, T, Grisham, LR, Heidbrink, W, Hill, KW, Hoffman, D, Jarboe, TR, Johnson, DW, Kaita, R, Kaye, SM, Kessel, C, Kim, JH, Kissick, MW, Kubota, S, Kugel, HW, LeBlanc, BP, Lee, K, Lee, SG, Lewicki, BT, Luckhardt, S, Maingi, R, Majeski, R, Manickam, J, Maqueda, R, Mau, TK, Mazzucato, E, Medley, SS, Menard, J, Mueller, D, Nelson, BA, Neumeyer, C, Nishino, N, Ostrander, CN, Pacella, D, Paoletti, F, Park, HK, Park, W, Paul, SF, Peng, YKM, Phillips, CK, Pinsker, R, Probert, PH, Ramakrishnan, S, Raman, R, Redi, M, Roquemore, AL, Rosenberg, A, Ryan, PM, Sabbagh, SA, Schaffer, M, Schooff, RJ, Seraydarian, R, Skinner, CH, Sontag, AC, Soukhanovskii, V, Spaleta, J, Stevenson, T, Stutman, D, Swain, DW, Synakowski, E, Takase, Y, Tang, X, Taylor, G, Timberlake, J, Tritz, KL, Unterberg, EA, von Halle, A, Wilgen, J, Williams, M, Wilson, JR, Xu, X, Zweben, SJ, Akers, R, Barry, RE, Beiersdorfer, P, Bialek, JM, Blagojevic, B, Bonoli, PT, Carter, MD, Davis, W, and Deng, B

Subjects

Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

Research on the spherical torus (or spherical tokamak) (ST) is being pursued to explore the scientific benefits of modifying the field line structue fro that in more moderate aspect ratio devices. The ST experiments are being conducted in various US research facilities. 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.

Published

2003

13. Alpha-particle physics in the tokamak fusion test reactor DT experiment

Author

Zweben, SJ, Arunasalam, V, Batha, SH, Budny, RV, Bush, CE, Cauffman, S, Chang, CS, Chang, Z, Cheng, CZ, Darrow, DS, Dendy, RO, Duong, HH, Fisch, NJ, Fredrickson, ED, Fisher, RK, Fonck, RJ, Fu, GY, Goloborod'ko, V, Gorelenkov, N, Hawryluk, RJ, Heeter, R, Heidbrink, WW, Herrmann, HW, Herrmann, M, Johnson, DW, Machuzak, J, Majeski, R, McGuire, KM, McKee, G, Medley, SS, Mynick, HE, Nazikian, R, Petrov, MP, Redi, MH, Reznik, S, Rogers, J, Schilling, G, Spong, DA, Strachan, JD, Stratton, BC, Synakowski, E, Taylor, G, Wang, S, White, RB, Wong, KL, Yavorski, V, and Group, the TFTR

Subjects

Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Fluids & Plasmas

Abstract

A summary is presented of recent alpha-particle experiments on the tokamak fusion test reactor. Alpha particles are generally well confined in MHD-quiescent discharges, and alpha heating of electrons has been observed. The theoretically predicted toroidicity-induced Alfvén eigenmode has been seen in discharges of ≤ 1 MW of alpha power, but only in plasmas with weak magnetic shear. © 1997 IOP Publishing Ltd.

Published

1997

14. Alpha-particle physics in the tokamak fusion test reactor DT experiment

Author

Zweben, SJ, Arunasalam, V, Batha, SH, Budny, RV, Bush, CE, Cauffman, S, Chang, CS, Chang, Z, Cheng, CZ, Darrow, DS, Dendy, RO, Duong, HH, Fisch, NJ, Fredrickson, ED, Fisher, RK, Fonck, RJ, Fu, GY, Goloborod'ko, V, Gorelenkov, N, Hawryluk, RJ, Heeter, R, Heidbrink, WW, Hermann, HW, Hermann, M, Johnson, DW, Machuzak, J, Majeski, R, McGuire, KM, McKee, G, Medley, SS, Mynick, HE, Nazikian, R, Petrov, MP, Redi, MH, Reznik, S, Rogers, J, Schilling, G, Spong, DA, Strachan, JD, Stratton, BC, Synakowski, E, Taylor, G, Wang, S, White, RB, Wong, KL, and Yavorski, V

Subjects

Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

A summary is presented of recent alpha-particle experiments on the tokamak fusion test reactor. Alpha particles are generally well confined in MHD-quiescent discharges, and alpha heating of electrons has been observed. The theoretically predicted toroidicity-induced Alfvén eigenmode has been seen in discharges of ≤ 1 MW of alpha power, but only in plasmas with weak magnetic shear. © 1997 IOP Publishing Ltd.

Published

1997

15. Alpha particle losses from Tokamak Fusion Test Reactor deuterium–tritium plasmas

Author

Darrow, DS, Zweben, SJ, Batha, S, Budny, RV, Bush, CE, Chang, Z, Cheng, CZ, Duong, HH, Fang, J, Fisch, NJ, Fischer, R, Fredrickson, ED, Fu, GY, Heeter, RF, Heidbrink, WW, Herrmann, HW, Herrmann, MC, Hill, K, Jaeger, EF, James, R, Majeski, R, Medley, SS, Murakami, M, Petrov, M, Phillips, CK, Redi, MH, Ruskov, E, Spong, DA, Strait, EJ, Taylor, G, White, RB, Wilson, JR, Wong, K-L, and Zarnstorff, MC

Subjects

Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Classical Physics, Fluids & Plasmas

Abstract

Because alpha particle losses can have a significant influence on tokamak reactor viability, the loss of deuterium–tritium alpha particles from the Tokamak Fusion Test Reactor (TFTR) [K. M. McGuire et al., Phys. Plasmas 2, 2176 (1995)] has been measured under a wide range of conditions. In TFTR, first orbit loss and stochastic toroidal field ripple diffusion are always present. Other losses can arise due to magnetohydrodynamic instabilities or due to waves in the ion cyclotron range of frequencies. No alpha particle losses have yet been seen due to collective instabilities driven by alphas. Ion Bernstein waves can drive large losses of fast ions from TFTR, and details of those losses support one element of the alpha energy channeling scenario. © 1996, American Institute of Physics. All rights reserved.

Published

1996

16. Alpha particle losses from Tokamak Fusion Test Reactor deuterium–tritium plasmas

Author

Darrow, DS, Zweben, SJ, Batha, S, Budny, RV, Bush, CE, Chang, Z, Cheng, CZ, Duong, HH, Fang, J, Fisch, NJ, Fischer, R, Fredrickson, ED, fu, GY, Heeter, RF, Heidbrink, WW, Herrmann, HW, Herrmann, MC, Hill, K, Jaeger, EF, James, R, Majeski, R, Medley, SS, Murakami, M, Petrov, M, Phillips, CK, Redi, MH, Ruskov, E, Spong, DA, Strait, EJ, Taylor, G, White, RB, Wilson, JR, Wong, KL, and Zarnstorff, MC

Subjects

Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Astronomical and Space Sciences, Classical Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

Because alpha particle losses can have a significant influence on tokamak reactor viability, the loss of deuterium–tritium alpha particles from the Tokamak Fusion Test Reactor (TFTR) [K. M. McGuire et al., Phys. Plasmas 2, 2176 (1995)] has been measured under a wide range of conditions. In TFTR, first orbit loss and stochastic toroidal field ripple diffusion are always present. Other losses can arise due to magnetohydrodynamic instabilities or due to waves in the ion cyclotron range of frequencies. No alpha particle losses have yet been seen due to collective instabilities driven by alphas. Ion Bernstein waves can drive large losses of fast ions from TFTR, and details of those losses support one element of the alpha energy channeling scenario. © 1996, American Institute of Physics. All rights reserved.

Published

1996

17. Overview of DT results from TFTR

Author

Bell, MG, McGuire, KM, Arunasalam, V, Barnes, CW, Batha, SH, Bateman, G, Beer, MA, Bell, RE, Bitter, M, Bretz, NL, Budny, RV, Bush, CE, Cauffman, SR, Chang, Z, Chang, C-S, Cheng, CZ, Darrow, DS, Dendy, RO, Dorland, W, Duong, HH, Durst, RD, Efthimion, PC, Ernst, D, Evenson, H, Fisch, NJ, Fisher, RK, Fonck, RJ, Fredrickson, ED, Fu, GY, Furth, HP, Gorelenkov, NN, Grek, B, Grisham, LR, Hammett, GW, Hanson, GR, Hawryluk, RJ, Heidbrink, WW, Herrmann, HW, Hill, KW, Hosea, JC, Hsuan, H, Hughes, MH, Hulse, RA, Janos, AC, Jassby, DL, Jobes, FC, Johnson, DW, Johnson, LC, Kesner, J, Kugel, HW, Lam, NT, Leblanc, B, Levinton, FM, Machuzak, J, Majeski, R, Mansfield, DK, Mazzucato, E, Mauel, ME, McChesney, JM, McCune, DC, McKee, G, Meade, DM, Medley, SS, Mikkelsen, DR, Mirnov, SV, Mueller, D, Navratil, GA, Nazikian, R, Owens, DK, Park, HK, Park, W, Parks, PB, Paul, SF, Petrov, MP, Phillips, CK, Phillips, MW, Pitcher, CS, Ramsey, AT, Redi, MH, Rewoldt, G, Roberts, DR, Rogers, JH, Ruskov, E, Sabbagh, SA, Sasao, M, Schilling, G, Schivell, JF, Schmidt, GL, Scott, SD, Semenov, I, Sesnic, S, Skinner, CH, Stratton, BC, Strachan, JD, Stodiek, W, Synakowski, EJ, Takahashi, H, Tang, WM, Taylor, G, and Terry, JL

Subjects

Atomic, Molecular, Nuclear, Particle and Plasma Physics, Fluids & Plasmas

Abstract

Experiments with plasmas having nearly equal concentrations of deuterium and tritium have been carried out on TFTR. To date (September 1995), the maximum fusion power has been 10.7 MW, using 39.5 MW of neutral beam heating, in a supershot discharge and 6.7 MW in a high beta P discharge following a current ramp-down. The fusion power density in the core of the plasma has reached 2.8 MW/m3, exceeding that expected in the International Thermonuclear Experimental Reactor (ITER). The energy confinement time tau E is observed to increase in DT, relative to D plasmas, by 20% and the n1(0).T1(0). tau E product by 55%. The improvement in thermal confinement is caused primarily by a decrease in ion heat conductivity in both supershot and limiter H mode discharges. Extensive lithium pellet injection increased the confinement time to 0.27 s and enabled higher current operation in both supershot and high beta P discharges. First measurements of the confined alpha particles have been performed and found to be in good agreement with TRANSP simulations assuming classical confinement. Measurements of the alpha ash profile have been compared with simulations using particle transport coefficients from helium gas puffing experiments. The loss of energetic alpha particles to a detector at the bottom of the vessel is well described by the first-orbit loss mechanism. No loss due to alpha particle driven instabilities has yet been observed. ICRF heating of a DT plasma, using the second harmonic of tritium, has been demonstrated. DT experiments on TFTR will continue both to explore the physics underlying the ITER design and to examine some of the physics issues associated with an advanced tokamak reactor.

Published

1995

18. Recent D-T results on TFTR

Author

Johnson, DW, Arunasalam, V, Barnes, CW, Batha, SH, Bateman, G, Beer, M, Bell, MG, Bell, R, Bitter, M, Bretz, NL, Budny, R, Bush, CE, Cauffman, S, Chang, CS, Chang, Z, Cheng, CZ, Darrow, DS, Dendy, R, Dorland, W, Duong, HH, Durst, R, Efthimion, PC, Ernst, D, Evenson, H, Fisch, N, Fisher, R, Fonck, RJ, Fredrickson, E, Fu, GY, Fujita, T, Furth, HP, Gorelenkov, N, Grek, B, Grisham, LR, Hammett, G, Hawryluk, RJ, Heidbrink, W, Herrmann, HW, Hill, KW, Hosea, J, Hsuan, H, Hughes, M, Janos, A, Jassby, DL, Jobes, FC, Johnson, LC, Kamperschroer, J, Kesner, J, Kotschenreuther, M, Kugel, H, Lamarche, PH, Leblanc, B, Levinton, FM, MacHuzak, J, Majeski, R, Mansfield, DK, Marmar, ES, Mazzucato, E, Mauel, M, McChesney, J, McGuire, KM, McKee, G, Meade, DM, Medley, SS, Mikkelsen, DR, Mirnov, SV, Mueller, D, Nazikian, R, Osakabe, M, Owens, DK, Park, H, Park, W, Parks, P, Paul, SF, Petrov, M, Phillips, CK, Phillips, M, Qualls, AL, Ramsey, A, Redi, MH, Rewoldt, G, Roberts, D, Rogers, J, Roquemore, AL, Ruskov, E, Sabbagh, SA, Sasao, M, Schilling, G, Schivell, J, Schmidt, GL, Scott, SD, Semenov, I, Sesnic, S, Skinner, CH, Spong, D, Stratton, BC, Strachan, JD, Stodiek, W, Synakowski, E, and Takahashi, H

Subjects

Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

Routine tritium operation in TFTR has permitted investigations of alpha particle physics in parameter ranges resembling those of a reactor core. ICRF wave physics in a DT plasma and the influence of isotopic mass on supershot confinement have also been studied. Continued progress has been made in optimizing fusion power production in TFTR, using extended machine capability and Li wall conditioning. Performance is currently limited by MHD stability. A new reversed magnetic shear regime is being investigated with reduced core transport and a higher predicted stability limit.

Published

1995

19. Overview of DT results from TFTR

Author

Bell, MG, McGuire, KM, Arunasalam, V, Barnes, CW, Batha, SH, Bateman, G, Beer, MA, Bell, RE, Bitter, M, Bretz, NI, Budny, RV, Bush, CE, Cauffman, SR, Chang, Z, Chang, CS, Cheng, CZ, Darrow, DS, Dendy, RO, Dorland, W, Duong, HH, Durst, RD, Efthimion, PC, Ernst, D, Evenson, H, Fisch, NJ, Fisher, RK, Fonck, RJ, Fredrickson, ED, Fu, GY, Furth, HP, Gorelenkov, NN, Grek, B, Grisham, LR, Hammett, GW, Hanson, GR, Hawryluk, RJ, Heidbrink, WW, Herrmann, HW, Hill, KW, Hosea, JC, Hsuan, H, Hughes, MH, Hulse, RA, Janos, AC, Jassby, DI, Jobes, FC, Johnson, DW, Johnson, LC, Kesner, J, Kugel, HW, Lam, NT, Leblanc, B, Levinton, FM, MacHuzak, J, Majeski, R, Mansfield, DK, Mazzucato, E, Mauel, ME, McChesney, JM, McCune, DC, McKee, G, Meade, DM, Medley, SS, Mikkelsen, DR, Mirnov, SV, Mueller, D, Navratil, GA, Nazikian, R, Owens, DK, Park, HK, Park, W, Parks, PB, Paul, SF, Petrov, MP, Phillips, CK, Phillips, MW, Pitcher, CS, Ramsey, AT, Redi, MH, Rewoldt, G, Roberts, DR, Rogers, JH, Ruskov, E, Sabbagh, SA, Sasao, M, Schilling, G, Schivell, JF, Schmidt, GI, Scott, SD, Semenov, I, Sesnic, S, Skinner, CH, Stratton, BC, Strachan, JD, Stodiek, W, Synakowski, EJ, Takahashi, H, Tang, WM, Taylor, G, and Terry, JI

Subjects

Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

Experiments with plasmas having nearly equal concentrations of deuterium and tritium have been carried out on TFTR. To date (September 1995), the maximum fusion power has been 10.7 MW, using 39.5 MW of neutral beam heating, in a supershot discharge and 6.7 MW in a high beta P discharge following a current ramp-down. The fusion power density in the core of the plasma has reached 2.8 MW/m3, exceeding that expected in the International Thermonuclear Experimental Reactor (ITER). The energy confinement time tau E is observed to increase in DT, relative to D plasmas, by 20% and the n1(0).T1(0). tau E product by 55%. The improvement in thermal confinement is caused primarily by a decrease in ion heat conductivity in both supershot and limiter H mode discharges. Extensive lithium pellet injection increased the confinement time to 0.27 s and enabled higher current operation in both supershot and high beta P discharges. First measurements of the confined alpha particles have been performed and found to be in good agreement with TRANSP simulations assuming classical confinement. Measurements of the alpha ash profile have been compared with simulations using particle transport coefficients from helium gas puffing experiments. The loss of energetic alpha particles to a detector at the bottom of the vessel is well described by the first-orbit loss mechanism. No loss due to alpha particle driven instabilities has yet been observed. ICRF heating of a DT plasma, using the second harmonic of tritium, has been demonstrated. DT experiments on TFTR will continue both to explore the physics underlying the ITER design and to examine some of the physics issues associated with an advanced tokamak reactor.

Published

1995

20. Recent D-T results on TFTR

Author

Johnson, DW, Arunasalam, V, Barnes, CW, Batha, SH, Bateman, G, Beer, M, Bell, MG, Bell, R, Bitter, M, Bretz, NL, Budny, R, Bush, CE, Cauffman, S, Chang, CS, Chang, Z, Cheng, CZ, Darrow, DS, Dendy, R, Dorland, W, Duong, HH, Durst, R, Efthimion, PC, Ernst, D, Evenson, H, Fisch, N, Fisher, R, Fonck, RJ, Fredrickson, E, Fu, GY, Fujita, T, Furth, HP, Gorelenkov, N, Grek, B, Grisham, LR, Hammett, G, Hawryluk, RJ, Heidbrink, W, Herrmann, HW, Hill, KW, Hosea, J, Hsuan, H, Hughes, M, Janos, A, Jassby, DL, Jobes, FC, Johnson, LC, Kamperschroer, J, Kesner, J, Kotschenreuther, M, Kugel, H, LaMarche, PH, Leblanc, B, Levinton, FM, Machuzak, J, Majeski, R, Mansfield, DK, Marmar, ES, Mazzucato, E, Mauel, M, McChesney, J, McGuire, KM, McKee, G, Meade, DM, Medley, SS, Mikkelsen, DR, Mirnov, SV, Mueller, D, Nazikian, R, Osakabe, M, Owens, DK, Park, H, Park, W, Parks, P, Paul, SF, Petrov, M, Phillips, CK, Phillips, M, Qualls, AL, Ramsey, A, Redi, MH, Rewoldt, G, Roberts, D, Rogers, J, Roquemore, AL, Ruskov, E, Sabbagh, SA, Sasao, M, Schilling, G, Schivell, J, Schmidt, GL, Scott, SD, Semenov, I, Sesnic, S, Skinner, CH, Spong, D, Stratton, BC, Strachan, JD, Stodiek, W, Synakowski, E, and Takahashi, H

Subjects

Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Fluids & Plasmas

Abstract

Routine tritium operation in TFTR has permitted investigations of alpha particle physics in parameter ranges resembling those of a reactor core. ICRF wave physics in a DT plasma and the influence of isotopic mass on supershot confinement have also been studied. Continued progress has been made in optimizing fusion power production in TFTR, using extended machine capability and Li wall conditioning. Performance is currently limited by MHD stability. A new reversed magnetic shear regime is being investigated with reduced core transport and a higher predicted stability limit.

Published

1995

21. Deuterium and tritium experiments on TFTR

Author

Strachan, JD, Adler, H, Barnes, CW, Batha, S, Bell, MG, Bell, R, Bitter, M, Bretz, NL, Budny, R, Bush, CE, Caorlin, M, Chang, Z, Darrow, DS, Duong, H, Durst, R, Efthimion, PC, Fisher, R, Fonck, RJ, Fredrickson, E, Grek, B, Grisham, LR, Hammett, G, Hawryiuk, RJ, Heidbrink, W, Herrmann, HW, Hill, KW, Hosea, J, Hsuan, H, Janos, A, Jassby, DL, Jobes, FC, Johnson, DW, Johnson, LC, Kugel, H, Lam, NT, LeBlanc, B, Levington, FM, Machuzak, J, Mansfield, DK, Mazzucato, E, Majeski, R, Marmar, E, McChesney, J, McGuire, KM, McKee, G, Meade, DM, Medley, SS, Mikkelsen, DR, Mueller, D, Murakami, M, Nazikian, R, Osakabe, M, Owens, DK, Park, H, Paul, SF, Petrov, M, Phillips, CK, Ramsey, AT, Redi, MH, Roberts, D, Rogers, J, Roquemore, AL, Ruskov, E, Sabbagh, SA, Sasao, M, Schilling, G, Schivell, J, Schmidt, GL, Scott, SD, Skinner, CH, Snipes, JA, Stevens, J, Stevenson, T, Stratton, BC, Synakowski, E, Taylor, G, Terry, JL, von Halle, A, von Goeler, S, Wilgen, JB, Wilson, JR, Wong, KL, Wurden, GA, Yamada, M, Young, KM, Zarnstorff, MC, and Zweben, SJ

Subjects

Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Fluids & Plasmas

Abstract

Three campaigns, prior to July 1994, attempted to increase the fusion power in DT plasmas on the Tokamak Fusion Test Reactor (TFTR). The first campaign was dedicated to obtaining >5 MW of fusion power while avoiding MHD events similar to the JET X-event. The second was aimed at producing maximum fusion power irrespective of proximity to MHD limits, and achieved 9 MW limited by a disruption. The third campaign increased the energy confinement time using lithium pellet conditioning while raising the ratio of alpha heating to beam heating.

Published

1994

22. Deuterium and tritium experiments on TFTR

Author

Strachan, JD, Adler, H, Barnes, CW, Batha, S, Bell, MG, Bell, R, Bitter, M, Bretz, NL, Budny, R, Bush, CE, Caorlin, M, Chang, Z, Darrow, DS, Duong, H, Durst, R, Efthimion, PC, Fisher, R, Fonck, RJ, Fredrickson, E, Grek, B, Grisham, LR, Hammett, G, Hawryiuk, RJ, Heidbrink, W, Herrmann, HW, Hill, KW, Hosea, J, Hsuan, H, Janos, A, Jassby, DL, Jobes, FC, Johnson, DW, Johnson, LC, Kugel, H, Lam, NT, LeBlanc, B, Levington, FM, Machuzak, J, Mansfield, DK, Mazzucato, E, Majeski, R, Marmar, E, McChesney, J, McGuire, KM, McKee, G, Meade, DM, Medley, SS, Mikkelsen, DR, Mueller, D, Murakami, M, Nazikian, R, Osakabe, M, Owens, DK, Park, H, Paul, SF, Petrov, M, Phillips, CK, Ramsey, AT, Redi, MH, Roberts, D, Rogers, J, Roquemore, AL, Ruskov, E, Sabbagh, SA, Sasao, M, Schilling, G, Schivell, J, Schmidt, GL, Scott, SD, Skinner, CH, Snipes, JA, Stevens, J, Stevenson, T, Stratton, BC, Synakowski, E, Taylor, G, Terry, JL, Von Halle, A, Von Goeler, S, Wilgen, JB, Wilson, JR, Wong, KL, Wurden, GA, Yamada, M, Young, KM, Zarnstorff, MC, and Zweben, SJ

Subjects

Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

Three campaigns, prior to July 1994, attempted to increase the fusion power in DT plasmas on the Tokamak Fusion Test Reactor (TFTR). The first campaign was dedicated to obtaining >5 MW of fusion power while avoiding MHD events similar to the JET X-event. The second was aimed at producing maximum fusion power irrespective of proximity to MHD limits, and achieved 9 MW limited by a disruption. The third campaign increased the energy confinement time using lithium pellet conditioning while raising the ratio of alpha heating to beam heating.

Published

1994