Bulletin of the American Physical Society
60th Annual Meeting of the APS Division of Plasma Physics
Volume 63, Number 11
Monday–Friday, November 5–9, 2018; Portland, Oregon
Session JP11: Poster Session IV: Education and Outreach; Undergraduate or High School Research; Plasma technology, Fusion reactor Nuclear and Materials Science; Propulsion; Materials Interfaces (2:00pm-5:00pm)
Tuesday, November 6, 2018
OCC
Room: Exhibit Hall A1&A
Abstract ID: BAPS.2018.DPP.JP11.43
Abstract: JP11.00043 : Impact of pedestal parameters on a controlled H-L back transition in DIII-D plasmas*
Presenter:
Cody Moynihan
(Univ of Illinois - Urbana)
Authors:
Cody Moynihan
(Univ of Illinois - Urbana)
Theresa M Wilks
(Massachusetts Inst of Tech-MIT)
David Eldon
(General Atomics - San Diego)
Orso Meneghini
(General Atomics - San Diego)
Sterling P Smith
(General Atomics - San Diego)
Xueqiao Xu
(Lawrence Livermore Natl Lab)
H-mode is a plasma mode characterized by an increased pressure gradient in the pedestal region, resulting in a transport barrier and increased confinement time. In future commercial reactors, it will be important to control the transitions in and out of H-mode. The H-L back transition can occur in a benign manner (soft transition) or abruptly, producing a large transient (hard transition). During hard transitions, a sudden increase in the Dα light can be seen at the divertor, which can indicate damaging high ion flux to the plasma-facing components. Although superficially similar to ELMs that occur during H-mode, it has been demonstrated that the instability resulting in the H-L transient is not the ideal peeling-ballooning mode responsible for type-I ELMs. Two fluid simulations using the BOUT++ code have shown that the transient associated with hard H-L transition is sensitive to toroidal rotation, which has also been seen in experiment. In the work presented here, BOUT++ simulations are used to match characteristics of pedestal instabilities observed in DIII-D plasmas and characterize mode dependencies on quantities like density, radial electric field, and rotation.
*Work supported in part by US DoE under the SULI program and under DE-FC02-04ER54698.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2018.DPP.JP11.43
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