Overview of the physics and engineering design of NSTX upgrade

Fusion Engineering(2011)

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摘要
The spherical tokamak (ST) is a leading candidate for a fusion nuclear science facility (FNSF) due to its compact size and modular configuration. The National Spherical Torus eXperiment (NSTX) is a MA-class ST facility in the U.S. actively developing the physics basis for an ST-based FNSF. In plasma transport research, ST experiments exhibit a strong (nearly inverse) scaling of normalized confinement with collisionality, and if this trend holds at low collisionality, high fusion neutron fluences could be achievable in very compact ST devices. A major motivation for the NSTX Upgrade (NSTX-U) is to span the next factor of 3-6 reduction in collisionality. To achieve this collisionality reduction with equilibrated profiles, NSTX-U will double the toroidal field, plasma current, and NBI heating power and increase the pulse length from 1-1.5s to 5s. In the area of stability and advanced scenarios, plasmas with higher aspect ratio and elongation, high βN, and broad current profiles approaching those of an ST-based FNSF have been produced in NSTX using active control of the plasma β and advanced resistive wall mode control. High non-inductive current fractions of 70% have been sustained for many current diffusion times, and the more tangential injection of the 2nd NBI of the Upgrade is projected to increase the NBI current drive by up to a factor of 2 and support 100% non-inductive operation. More tangential NBI injection is also projected to provide non-solenoidal current ramp-up (from IP = 0.4MA up to 0.8-1MA) as needed for an ST-based FNSF. In boundary physics, NSTX and higher-A tokamaks measure an inverse relationship between the scrape-off layer heat-flux width and plasma current that could unfavorably impact next-step devices. Recently, NSTX has successfully demonstrated very high flux expansion and substantial heat-flux reduction using a snowflake divertor configuration, and this type of divertor is incorporated in the NSTX-U des- - ign. The physics and engineering design supporting NSTX Upgrade are described.
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关键词
tokamak devices,fusion reactor design,fusion reactor divertors,plasma heating,plasma toroidal confinement,plasma transport processes,nbi heating power,nstx upgrade,national spherical torus experiment,aspect ratio,compact size configuration,diffusion times,engineering design,fusion neutron fluences,fusion nuclear science facility,heat-flux width,modular configuration,noninductive current fractions,nonsolenoidal current ramp-up,normalized confinement scaling,physics design,plasma beta active control,plasma current,plasma transport research,resistive wall mode control,snowflake divertor configuration,spherical tokamak,tangential injection,toroidal field,heat flux,solenoids,thermal stability,radio frequency,magnetic confinement,lead
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