Your search keyword '"Sips, Acc"' showing total 6 results

1. Progress towards high-performance steady-state operation on DIII-D

Author

Greenfield, CM, Murakami, M, Garofalo, AM, Doyle, EJ, Ferron, JR, Wade, MR, Austin, ME, Allen, SL, Burrell, KH, Casper, TA, DeBoo, JC, Gohil, P, Gorelov, IA, Groebner, RJ, Heidbrink, WW, Hyatt, AW, Jackson, GL, Jayakumar, RJ, Kajiwara, K, Kessel, CE, Kinsey, JE, Kim, JY, La Haye, RJ, Lao, LL, Lohr, J, Luce, TC, Luo, Y, Makowski, MA, Mazon, D, McKee, GR, Okabayashi, M, Osborne, TH, Petty, CC, Petrie, TW, Pinsker, RI, Prater, R, Politzer, PA, Reimerdes, H, Rhodes, TL, Sips, ACC, Scoville, JT, Solomon, WM, Staebler, GM, St. John, HE, Strait, EJ, Taylor, TS, Turnbull, AD, Van Zeeland, MA, Wang, G, West, WP, Zeng, L, and Team, the DIII-D

Subjects

tokamak, steady-state, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Mechanical Engineering, Interdisciplinary Engineering, Energy

Abstract

Advanced Tokamak research in DIII-D seeks to develop a scientific basis for steady-state high-performance tokamak operation. Fully noninductive (fNI ≈ 100%) in-principle steady-state discharges have been maintained for several confinement times. These plasmas have weak negative central shear with qmin ≈ 1.5-2, βN ≈ 3.5, and large, well-aligned bootstrap current. The loop voltage is near zero across the entire profile. The remaining current is provided by neutral beam current drive (NBCD) and electron cyclotron current drive (ECCD). Similar plasmas are stationary with fNI ≈ 90-95% and duration up to 2 s, limited only by hardware. In other experiments, βN ≈ 4 is maintained for 2 s with internal transport barriers, exceeding previously achieved performance under similar conditions. This is allowed by broadened profiles and active magnetohydrodynamic instability control. Modifications now underway on DIII-D are expected to allow extension of these results to higher performance and longer duration. A new pumped divertor will allow density control in high triangularity double-null divertor configurations, facilitating access to similar in-principle steady-state regimes with βN > 4. Additional current drive capabilities, both off-axis ECCD and on-axis fast wave current drive (FWCD), will increase the magnitude, duration, and flexibility of externally driven current. © 2006 Elsevier B.V. All rights reserved.

Published

2006

2. Progress towards high-performance steady-state operation on DIII-D

Author

Greenfield, CM, Murakami, M, Garofalo, AM, Doyle, EJ, Ferron, JR, Wade, MR, Austin, ME, Allen, SL, Burrell, KH, Casper, TA, DeBoo, JC, Gohil, P, Gorelov, IA, Groebner, RJ, Heidbrink, WW, Hyatt, AW, Jackson, GL, Jayakumar, RJ, Kajiwara, K, Kessel, CE, Kinsey, JE, Kim, JY, La Haye, RJ, Lao, LL, Lohr, J, Luce, TC, Luo, Y, Makowski, MA, Mazon, D, McKee, GR, Okabayashi, M, Osborne, TH, Petty, CC, Petrie, TW, Pinsker, RI, Prater, R, Politzer, PA, Reimerdes, H, Rhodes, TL, Sips, ACC, Scoville, JT, Solomon, WM, Staebler, GM, St. John, HE, Strait, EJ, Taylor, TS, Turnbull, AD, Van Zeeland, MA, Wang, G, West, WP, and Zeng, L

Subjects

tokamak, steady-state, Energy, Mechanical Engineering, Interdisciplinary Engineering, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

Advanced Tokamak research in DIII-D seeks to develop a scientific basis for steady-state high-performance tokamak operation. Fully noninductive (fNI ≈ 100%) in-principle steady-state discharges have been maintained for several confinement times. These plasmas have weak negative central shear with qmin ≈ 1.5-2, βN ≈ 3.5, and large, well-aligned bootstrap current. The loop voltage is near zero across the entire profile. The remaining current is provided by neutral beam current drive (NBCD) and electron cyclotron current drive (ECCD). Similar plasmas are stationary with fNI ≈ 90-95% and duration up to 2 s, limited only by hardware. In other experiments, βN ≈ 4 is maintained for 2 s with internal transport barriers, exceeding previously achieved performance under similar conditions. This is allowed by broadened profiles and active magnetohydrodynamic instability control. Modifications now underway on DIII-D are expected to allow extension of these results to higher performance and longer duration. A new pumped divertor will allow density control in high triangularity double-null divertor configurations, facilitating access to similar in-principle steady-state regimes with βN > 4. Additional current drive capabilities, both off-axis ECCD and on-axis fast wave current drive (FWCD), will increase the magnitude, duration, and flexibility of externally driven current. © 2006 Elsevier B.V. All rights reserved.

Published

2006

3. Progress toward fully noninductive, high beta conditions in DIII-Da)

Author

Murakami, M, Wade, MR, Greenfield, CM, Luce, TC, Ferron, JR, John, HE St, DeBoo, JC, Heidbrink, WW, Luo, Y, Makowski, MA, Osborne, TH, Petty, CC, Politzer, PA, Allen, SL, Austin, ME, Burrell, KH, Casper, TA, Doyle, EJ, Garofalo, AM, Gohil, P, Gorelov, IA, Groebner, RJ, Hyatt, AW, Jayakumar, RJ, Kajiwara, K, Kessel, CE, Kinsey, JE, La Haye, RJ, Lao, LL, Leonard, AW, Lohr, J, Petrie, TW, Pinsker, RI, Prater, R, Rhodes, TL, Sips, ACC, Staebler, GM, Taylor, TS, Vanzeeland, MA, Wang, G, West, WP, Zeng, L, and Team, the DIII-D

Subjects

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

Abstract

The DIII-D Advanced Tokamak (AT) program in the DIII-D tokamak [J. L. Luxon, Plasma Physics and Controlled Fusion Research, 1986, Vol. I (International Atomic Energy Agency, Vienna, 1987), p. 159] is aimed at developing a scientific basis for steady-state, high-performance operation in future devices. This requires simultaneously achieving 100% noninductive operation with high self-driven bootstrap current fraction and toroidal beta. Recent progress in this area includes demonstration of 100% noninductive conditions with toroidal beta, ΒT =3.6%, normalized beta, ΒN =3.5, and confinement factor, H89 =2.4 with the plasma current driven completely by bootstrap, neutral beam current drive, and electron cyclotron current drive (ECCD). The equilibrium reconstructions indicate that the noninductive current profile is well aligned, with little inductively driven current remaining anywhere in the plasma. The current balance calculation improved with beam ion redistribution that was supported by recent fast ion diagnostic measurements. The duration of this state is limited by pressure profile evolution, leading to magnetohydrodynamic (MHD) instabilities after about 1 s or half of a current relaxation time (τCR). Stationary conditions are maintained in similar discharges (∼90% noninductive), limited only by the 2 s duration (1 τCR) of the present ECCD systems. By discussing parametric scans in a global parameter and profile databases, the need for low density and high beta are identified to achieve full noninductive operation and good current drive alignment. These experiments achieve the necessary fusion performance and bootstrap fraction to extrapolate to the fusion gain, Q=5 steady-state scenario in the International Thermonuclear Experimental Reactor (ITER) [R. Aymar, Fusion Energy Conference on Controlled Fusion and Plasma Physics, Sorrento, Italy (International Atomic Energy Agency, Vienna, 1987), paper IAEA-CN-77/OV-1]. The modeling tools that have been successfully employed to both plan and interpret the experiment are used to plan future DIII-D experiments with higher power and longer pulse ECCD and fast wave and co- and counterneutral beam injection in a pumped double-null configuration. The models predict our ability to control the current and pressure profiles to reach full noninductivity with increased beta, bootstrap fraction, and duration. The same modeling tools are applied to ITER, predicting favorable prospects for the success of the ITER steady-state scenario. © 2006 American Institute of Physics.

Published

2006

4. Progress toward fully noninductive, high beta conditions in DIII-D

Author

Murakami, M, Wade, MR, Greenfield, CM, Luce, TC, Ferron, JR, John, HES, Deboo, JC, Heidbrink, WW, Luo, Y, Makowski, MA, Osborne, TH, Petty, CC, Politzer, PA, Allen, SL, Austin, ME, Burrell, KH, Casper, TA, Doyle, EJ, Garofalo, AM, Gohil, P, Gorelov, IA, Groebner, RJ, Hyatt, AW, Jayakumar, RJ, Kajiwara, K, Kessel, CE, Kinsey, JE, La Haye, RJ, Lao, LL, Leonard, AW, Lohr, J, Petrie, TW, Pinsker, RI, Prater, R, Rhodes, TL, Sips, ACC, Staebler, GM, Taylor, TS, Vanzeeland, MA, Wang, G, West, WP, and Zeng, L

Subjects

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

Abstract

The DIII-D Advanced Tokamak (AT) program in the DIII-D tokamak [J. L. Luxon, Plasma Physics and Controlled Fusion Research, 1986, Vol. I (International Atomic Energy Agency, Vienna, 1987), p. 159] is aimed at developing a scientific basis for steady-state, high-performance operation in future devices. This requires simultaneously achieving 100% noninductive operation with high self-driven bootstrap current fraction and toroidal beta. Recent progress in this area includes demonstration of 100% noninductive conditions with toroidal beta, ΒT =3.6%, normalized beta, ΒN =3.5, and confinement factor, H89 =2.4 with the plasma current driven completely by bootstrap, neutral beam current drive, and electron cyclotron current drive (ECCD). The equilibrium reconstructions indicate that the noninductive current profile is well aligned, with little inductively driven current remaining anywhere in the plasma. The current balance calculation improved with beam ion redistribution that was supported by recent fast ion diagnostic measurements. The duration of this state is limited by pressure profile evolution, leading to magnetohydrodynamic (MHD) instabilities after about 1 s or half of a current relaxation time (τCR). Stationary conditions are maintained in similar discharges (∼90% noninductive), limited only by the 2 s duration (1 τCR) of the present ECCD systems. By discussing parametric scans in a global parameter and profile databases, the need for low density and high beta are identified to achieve full noninductive operation and good current drive alignment. These experiments achieve the necessary fusion performance and bootstrap fraction to extrapolate to the fusion gain, Q=5 steady-state scenario in the International Thermonuclear Experimental Reactor (ITER) [R. Aymar, Fusion Energy Conference on Controlled Fusion and Plasma Physics, Sorrento, Italy (International Atomic Energy Agency, Vienna, 1987), paper IAEA-CN-77/OV-1]. The modeling tools that have been successfully employed to both plan and interpret the experiment are used to plan future DIII-D experiments with higher power and longer pulse ECCD and fast wave and co- and counterneutral beam injection in a pumped double-null configuration. The models predict our ability to control the current and pressure profiles to reach full noninductivity with increased beta, bootstrap fraction, and duration. The same modeling tools are applied to ITER, predicting favorable prospects for the success of the ITER steady-state scenario. © 2006 American Institute of Physics.

Published

2006

5. Stability in high gain plasmas in DIII-D*

Author

Lazarus, EA, Navratil, GA, Strait, EJ, Rice, BW, Ferron, JR, Greenfield, CM, Austin, ME, Baker, DR, Burrell, KH, Casper, TA, Chan, VS, DeBoo, JC, Doyle, EJ, Durst, RD, Forest, CB, Gohil, P, Groebner, RJ, Heidbrink, WW, Hong, RM, Houlberg, WA, Howald, AW, Hsieh, CL, Hyatt, AW, Jackson, GL, Kim, J, La Haye, RJ, Lao, LL, Lasnier, CJ, Leonard, AW, Lohr, J, Maingi, R, Murakami, M, Osborne, TH, Perkins, LJ, Petty, CC, Rettig, CL, Rhodes, TL, Sabbagh, SA, Schissel, DP, Scoville, JT, Sips, ACC, Snider, RT, Soldner, FX, St John, HE, Staebler, GM, Stallard, BW, Stambaugh, RD, Stockdale, RE, Taylor, PL, Taylor, TS, Thomas, DM, Turnbull, AD, Wade, MR, Whyte, DG, Wood, RD, and AGCY, INT ATOMIC ENERGY

Published

1997

6. Stability in high gain plasmas in DIII-D*

Author

Lazarus, EA, Navratil, GA, Strait, EJ, Rice, BW, Ferron, JR, Greenfield, CM, Austin, ME, Baker, DR, Burrell, KH, Casper, TA, Chan, VS, DeBoo, JC, Doyle, EJ, Durst, RD, Forest, CB, Gohil, P, Groebner, RJ, Heidbrink, WW, Hong, RM, Houlberg, WA, Howald, AW, Hsieh, CL, Hyatt, AW, Jackson, GL, Kim, J, La Haye, RJ, Lao, LL, Lasnier, CJ, Leonard, AW, Lohr, J, Maingi, R, Murakami, M, Osborne, TH, Perkins, LJ, Petty, CC, Rettig, CL, Rhodes, TL, Sabbagh, SA, Schissel, DP, Scoville, JT, Sips, ACC, Snider, RT, Soldner, FX, St John, HE, Staebler, GM, Stallard, BW, Stambaugh, RD, Stockdale, RE, Taylor, PL, Taylor, TS, Thomas, DM, Turnbull, AD, Wade, MR, Whyte, DG, and Wood, RD

Published

1997