Your search keyword '"West, W WPW"' showing total 2 results

1. ELM suppression in low edge collisionality H-mode discharges using n = 3 magnetic perturbations

Author

Burrell, K KHB, Evans, T TEE, Doyle, E EJD, Fenstermacher, M MEF, Groebner, R RJG, Leonard, A AWL, Moyer, R RAM, Osborne, T THO, Schaffer, M MJS, Snyder, P PBS, Thomas, P PRT, West, W WPW, Boedo, J JAB, Garofalo, A AMG, Gohil, P PG, Jackson, G GLJ, Haye, R RJL La, Lasnier, C CJL, Reimerdes, H HR, Rhodes, T TLR, Scoville, J JTS, Solomon, W WMS, Thomas, D DMT, Wang, G GW, Watkins, J JGW, and Zeng, L LZ

Abstract

Using resonant magnetic perturbations with toroidal mode number n = 3, we have produced H-mode discharges without edge localized modes (ELMs) which run with constant density and radiated power for periods up to about 2550 ms (17 energy confinement times). These ELM suppression results are achieved at pedestal collisionalities close to those desired for next step burning plasma experiments such as ITER and provide a means of eliminating the rapid erosion of divertor components in such machines which could be caused by giant ELMs. The ELM suppression is due to an enhancement in the edge particle transport which reduces pedestal current density and maximum edge pressure gradient below the threshold for peeling–ballooning modes. These n = 3 magnetic perturbations provide a means of active control of edge plasma transport.

Published

2005

2. Advanced tokamak research in DIII-D

Author

Greenfield, C CMG, Murakami, M MM, Ferron, J JRF, Wade, M MRW, Luce, T TCL, Petty, C CCP, Menard, J JEM, Petrie, T TWP, Allen, S SLA, Burrell, K KHB, Casper, T TAC, DeBoo, J JCD, Doyle, E EJD, Garofalo, A AMG, Gorelov, I IAG, Groebner, R RJG, Hobirk, J JH, Hyatt, A AWH, Jayakumar, R RJJ, Kessel, C CEK, Haye, R RJL La, Jackson, G GLJ, Lao, L LLL, Lohr, J JL, Makowski, M MAM, Pinsker, R RIP, Politzer, P PAP, Prater, R RP, Staebler, G GMS, Strait, E EJS, Taylor, T TST, West, W WPW, and Team, the tDT

Abstract

Advanced tokamak (AT) research in DIII-D seeks to provide a scientific basis for steady-state high performance operation in future devices. These regimes require high toroidal beta to maximize fusion output and high poloidal beta to maximize the self-driven bootstrap current. Achieving these conditions requires integrated, simultaneous control of the current and pressure profiles and active magnetohydrodynamic stability control. The building blocks for AT operation are in hand. Resistive wall mode stabilization by plasma rotation and active feedback with non-axisymmetric coils allows routine operation above the no-wall beta limit. Neoclassical tearing modes are stabilized by active feedback control of localized electron cyclotron current drive (ECCD). Plasma shaping and profile control provide further improvements. Under these conditions, bootstrap supplies most of the current. Steady-state operation requires replacing the remaining inductively driven current, mostly located near the half radius, with non-inductive external sources. In DIII-D this current is provided by ECCD, and nearly stationary AT discharges have been sustained with little remaining inductive current. Fast wave current drive is being developed to control the central magnetic shear. Density control, with divertor cryopumps, of AT discharges with ELMing H-mode edges facilitates high current drive efficiency at reactor relevant collisionalities. An advanced plasma control system allows integrated control of these elements. Close coupling between modelling and experiment is key to understanding the separate elements, their complex nonlinear interactions, and their integration into self-consistent high performance scenarios. This approach has resulted in fully non-inductively driven plasmas with βN ≤ 3.5 and βT ≤ 3.6% sustained for up to 1 s, which is approximately equal to one current relaxation time. Progress in this area, and its implications for next-step devices, will be illustrated by results of these and other recent experiment and simulation efforts.

Published

2004