Your search keyword '"Walk, J."' showing total 6 results

1. Improved understanding of physics processes in pedestal structure, leading to improved predictive capability for ITER

Author

Groebner, RJ, Chang, CS, Hughes, JW, Maingi, R, Snyder, PB, Xu, XQ, Boedo, JA, Boyle, DP, Callen, JD, Canik, JM, Cziegler, I, Davis, EM, Diallo, A, Diamond, PH, Elder, JD, Eldon, DP, Ernst, DR, Fulton, DP, Landreman, M, Leonard, AW, Lore, JD, Osborne, TH, Pankin, AY, Parker, SE, Rhodes, TL, Smith, SP, Sontag, AC, Stacey, WM, Walk, J, Wan, W, Wang, EH-J, Watkins, JG, White, AE, Whyte, DG, Yan, Z, Belli, EA, Bray, BD, Candy, J, Churchill, RM, Deterly, TM, Doyle, EJ, Fenstermacher, ME, Ferraro, NM, Hubbard, AE, Joseph, I, Kinsey, JE, LaBombard, B, Lasnier, CJ, Lin, Z, Lipschultz, BL, Liu, C, Ma, Y, McKee, GR, Ponce, DM, Rost, JC, Schmitz, L, Staebler, GM, Sugiyama, LE, Terry, JL, Umansky, MV, Waltz, RE, Wolfe, SM, Zeng, L, and Zweben, SJ

Subjects

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

Abstract

Joint experiment/theory/modelling research has led to increased confidence in predictions of the pedestal height in ITER. This work was performed as part of a US Department of Energy Joint Research Target in FY11 to identify physics processes that control the H-mode pedestal structure. The study included experiments on C-Mod, DIII-D and NSTX as well as interpretation of experimental data with theory-based modelling codes. This work provides increased confidence in the ability of models for peeling-ballooning stability, bootstrap current, pedestal width and pedestal height scaling to make correct predictions, with some areas needing further work also being identified. A model for pedestal pressure height has made good predictions in existing machines for a range in pressure of a factor of 20. This provides a solid basis for predicting the maximum pedestal pressure height in ITER, which is found to be an extrapolation of a factor of 3 beyond the existing data set. Models were studied for a number of processes that are proposed to play a role in the pedestal ne and Te profiles. These processes include neoclassical transport, paleoclassical transport, electron temperature gradient turbulence and neutral fuelling. All of these processes may be important, with the importance being dependent on the plasma regime. Studies with several electromagnetic gyrokinetic codes show that the gradients in and on top of the pedestal can drive a number of instabilities. © 2013 IAEA, Vienna.

Published

2013

2. ADX: a high field, high power density, advanced divertor and RF tokamak

Author

LaBombard, B., primary, Marmar, E., additional, Irby, J., additional, Terry, J.L., additional, Vieira, R., additional, Wallace, G., additional, Whyte, D.G., additional, Wolfe, S., additional, Wukitch, S., additional, Baek, S., additional, Beck, W., additional, Bonoli, P., additional, Brunner, D., additional, Doody, J., additional, Ellis, R., additional, Ernst, D., additional, Fiore, C., additional, Freidberg, J.P., additional, Golfinopoulos, T., additional, Granetz, R., additional, Greenwald, M., additional, Hartwig, Z.S., additional, Hubbard, A., additional, Hughes, J.W., additional, Hutchinson, I.H., additional, Kessel, C., additional, Kotschenreuther, M., additional, Leccacorvi, R., additional, Lin, Y., additional, Lipschultz, B., additional, Mahajan, S., additional, Minervini, J., additional, Mumgaard, R., additional, Nygren, R., additional, Parker, R., additional, Poli, F., additional, Porkolab, M., additional, Reinke, M.L., additional, Rice, J., additional, Rognlien, T., additional, Rowan, W., additional, Shiraiwa, S., additional, Terry, D., additional, Theiler, C., additional, Titus, P., additional, Umansky, M., additional, Valanju, P., additional, Walk, J., additional, White, A., additional, Wilson, J.R., additional, Wright, G., additional, and Zweben, S.J., additional

Published

2015

3. Reduction of core turbulence in I-mode plasmas in Alcator C-Mod

Author

White, A.E., primary, Barnes, M., additional, Dominguez, A., additional, Greenwald, M., additional, Howard, N.T., additional, Hubbard, A.E., additional, Hughes, J.W., additional, Mikkelsen, D.R., additional, Parra, F.I., additional, Reinke, M.L., additional, Sung, C., additional, Walk, J., additional, and Whyte, D.G., additional

Published

2014

4. Overview of experimental results and code validation activities at Alcator C-Mod

Author

Greenwald, M., primary, Bader, A., additional, Baek, S., additional, Barnard, H., additional, Beck, W., additional, Bergerson, W., additional, Bespamyatnov, I., additional, Bitter, M., additional, Bonoli, P., additional, Brookman, M., additional, Brower, D., additional, Brunner, D., additional, Burke, W., additional, Candy, J., additional, Chilenski, M., additional, Chung, M., additional, Churchill, M., additional, Cziegler, I., additional, Davis, E., additional, Dekow, G., additional, Delgado-Aparicio, L., additional, Diallo, A., additional, Ding, W., additional, Dominguez, A., additional, Ellis, R., additional, Ennever, P., additional, Ernst, D., additional, Faust, I., additional, Fiore, C., additional, Fitzgerald, E., additional, Fredian, T., additional, Garcia, O.E., additional, Gao, C., additional, Garrett, M., additional, Golfinopoulos, T., additional, Granetz, R., additional, Groebner, R., additional, Harrison, S., additional, Harvey, R., additional, Hartwig, Z., additional, Hill, K., additional, Hillairet, J., additional, Howard, N., additional, Hubbard, A.E., additional, Hughes, J.W., additional, Hutchinson, I., additional, Irby, J., additional, James, A.N., additional, Kanojia, A., additional, Kasten, C., additional, Kesner, J., additional, Kessel, C., additional, Kube, R., additional, LaBombard, B., additional, Lau, C., additional, Lee, J., additional, Liao, K., additional, Lin, Y., additional, Lipschultz, B., additional, Ma, Y., additional, Marmar, E., additional, McGibbon, P., additional, Meneghini, O., additional, Mikkelsen, D., additional, Miller, D., additional, Mumgaard, R., additional, Murray, R., additional, Ochoukov, R., additional, Olynyk, G., additional, Pace, D., additional, Park, S., additional, Parker, R., additional, Podpaly, Y., additional, Porkolab, M., additional, Preynas, M., additional, Pusztai, I., additional, Reinke, M., additional, Rice, J., additional, Rowan, W., additional, Scott, S., additional, Shiraiwa, S., additional, Sierchio, J., additional, Snyder, P., additional, Sorbom, B., additional, Soukhanovskii, V., additional, Stillerman, J., additional, Sugiyama, L., additional, Sung, C., additional, Terry, D., additional, Terry, J., additional, Theiler, C., additional, Tsujii, N., additional, Vieira, R., additional, Walk, J., additional, Wallace, G., additional, White, A., additional, Whyte, D., additional, Wilson, J., additional, Wolfe, S., additional, Woller, K., additional, Wright, G., additional, Wright, J., additional, Wukitch, S., additional, Wurden, G., additional, Xu, P., additional, Yang, C., additional, and Zweben, S., additional

Published

2013

5. Changes in core electron temperature fluctuations across the ohmic energy confinement transition in Alcator C-Mod plasmas.

Author

Sung, C., White, A. E., Howard, N. T., Oi, C. Y., Rice, J. E., Gao, C., Ennever, P., Porkolab, M., Parra, F., Mikkelsen, D., Ernst, D., Walk, J., Hughes, J. W., Irby, J., Kasten, C., Hubbard, A. E., and Greenwald, M. J.

Subjects

ELECTRON temperature, RESISTANCE heating, WAVELENGTHS, TURBULENCE, MOMENTUM (Mechanics), ELECTRIC heating

Abstract

The first measurements of long wavelength (kyps < 0.3) electron temperature fluctuations in Alcator C-Mod made with a new correlation electron cyclotron emission diagnostic support a long-standing hypothesis regarding the confinement transition from linear ohmic confinement (LOC) to saturated ohmic confinement (SOC). Electron temperature fluctuations decrease significantly (~40%) crossing from LOC to SOC, consistent with a change from trapped electron mode (TEM) turbulence domination to ion temperature gradient (ITG) turbulence as the density is increased. Linear stability analysis performed with the GYRO code (Candy and Waltz 2003 J. Comput. Phys. 186 545) shows that TEMs are dominant for long wavelength turbulence in the LOC regime and ITG modes are dominant in the SOC regime at the radial location (p ~ 0.8) where the changes in electron temperature fluctuations are measured. In contrast, deeper in the core (p < 0.8), linear stability analysis indicates that ITG modes remain dominant across the LOC/SOC transition. This radial variation suggests that the robust global changes in confinement of energy and momentum occurring across the LOC/SOC transition are correlated to local changes in the dominant turbulent mode near the edge. [ABSTRACT FROM AUTHOR]

Published

2013

6. Characterization of the pedestal in Alcator C-Mod ELMing H-modes and comparison with the EPED model.

Author

Walk, J. R., Snyder, P. B., Hughes, J. W., Terry, J. L., Hubbard, A. E., and Phillips, P. E.

Subjects

*NUCLEAR fusion, *MATHEMATICAL models, *PLASMA gases, *GLOW discharges, *MAGNETIC fields, *ITERATIVE methods (Mathematics), *PARAMETER estimation

Abstract

A dedicated series of ELMing H-mode discharges on Alcator C-Mod spanning a broad range of plasma parameters, including plasma current (400-1000 kA), magnetic field (3.5-8 T), and plasma shaping, are presented with experimental scalings of the plasma pedestal with bulk plasma and engineering parameters. The H-modes presented achieve pedestals with densities spanning 5×1019-2.5×1020 m-3 and temperatures of 150-1000 eV (corresponding to 5-40 kPa in the pressure pedestal), over a width of 3-5% of poloidal flux. The observed pedestal structure is compared with the most recent iteration of the EPED class of models, which uniquely predict the pedestal width and height for a set of scalar input parameters via a combination of stability calculations for peeling-ballooning MHD modes and kinetic-ballooning modes. [ABSTRACT FROM AUTHOR]

Published

2012