Skip to main content
OSTI.GOVU.S. Department of Energy Office of Scientific and Technical Information
U.S. Department of Energy
Office of Scientific and Technical Information
 

Recycling and particle control in DIII--D

Journal Article · · Journal of Vacuum Science and Technology, A (Vacuum, Surfaces and Films); (United States)
DOI:https://doi.org/10.1116/1.578234· OSTI ID:7182019
 [1]
  1. General Atomics, P.O. Box 85608, San Diego, California 92186-9784 (United States)
+ Show Author Affiliations

Particle control of both hydrogen and impurity atoms is important in obtaining reproducible discharges with a low fraction of radiated power in the DIII--D tokamak. The main DIII--D plasma facing components are graphite tiles (40% of the total area and covering regions exposed to the highest heat fluxes) and Inconel. Hydrogenic species desorbed from graphite during a tokamak discharge can be a major fueling source, especially in unconditioned graphite where these species can saturate the surface regions. In this case the recycling coefficient can exceed unity, leading to an uncontrolled density rise. In addition to removing volatile hydrocarbons and oxygen, DIII--D vessel conditioning efforts have been directed at the reduction of particle fueling from the graphite tiles. Conditioning techniques include: baking to {le}400 {degree}C, low power pulsed discharge cleaning, and glow discharges in deuterium, helium, neon, or argon. Helium glow wall conditioning, is now routinely performed before every tokamak discharge. The effects of these techniques on hydrogen recycling and impurity influxes are presented. The Inconel walls, while not generally exposed to high heat fluxes, nevertheless represent a source of metal impurities which can lead to impurity accumulation in the discharge and a high fraction of radiated power, particularly in H-mode discharges at higher plasma currents, {ital I}{sub {ital p}} {gt} 1.5 MA. To reduce metal influx a thin ({similar to}100 nm) low {ital Z} film (carbon or boron) has been applied on all plasma facing surfaces in DIII--D. The application of the boron film, referred to as boronization, has the additional benefit over a carbon film (carbonization) of further reducing the oxygen influx. Following the first boronization in DIII--D a regime of very high confinement (VH-mode) was observed, characterized by low ohmic target density, low {ital Z}{sub eff}, and low radiated power.

DOE Contract Number:
AC03-89ER51114
OSTI ID:
7182019
Journal Information:
Journal of Vacuum Science and Technology, A (Vacuum, Surfaces and Films); (United States), Journal Name: Journal of Vacuum Science and Technology, A (Vacuum, Surfaces and Films); (United States) Vol. 10:4; ISSN JVTAD; ISSN 0734-2101
Country of Publication:
United States
Language:
English

Similar Records

Recycling and particle control in DIII-D
Conference · Thu Oct 31 23:00:00 EST 1991 · OSTI ID:6014752
Recycling and particle control in DIII-D
Conference · Thu Oct 31 23:00:00 EST 1991 · OSTI ID:10121980
Helium glow wall conditioning of the DIII-D tokamak with large area graphite coverage
Conference · Sun Feb 04 23:00:00 EST 1990 · AIP Conference Proceedings (American Institute of Physics); (USA) · OSTI ID:6690876

Related Subjects

70 PLASMA PHYSICS AND FUSION TECHNOLOGY
700420* -- Fusion Technology-- Plasma-Facing Components-- (1992-)
BORON
CARBON
CLOSED PLASMA DEVICES
ELEMENTS
IMPURITIES
NONMETALS
PLASMA DENSITY
PLASMA IMPURITIES
POWER DENSITY
REPROCESSING
SEMIMETALS
SEPARATION PROCESSES
THERMONUCLEAR DEVICES
TOKAMAK DEVICES
WALL LOADING