Sustained Suppression of Type-I Edge Localized Modes with Dominantly n=2 Magnetic Fields in DIII-D

M.J. Lanctot; M.E. Fenstermacher; I. Joseph; R.J. Buttery; M.R. Wade; T.E. Evans; N.M. Ferraro; J.S. deGrassie; Philip Snyder; R. Nazikian; R.A. Moyer; D.M. Orlov; J.M. Hanson; W. Suttrop; S. Haskey

Sustained Suppression of Type-I Edge Localized Modes with Dominantly n=2 Magnetic Fields in DIII-D

POSTER

Abstract

Type-I edge-localized modes (ELMs) are suppressed in DIII-D using magnetic perturbations with dominant toroidal mode number $n=2$. ELM suppression is obtained with two rows of internal coils for 1.8 s with normalized beta of 1.9 and average triangularity of 0.53 corresponding to a scaled version of ITER scenario 2 at an ITER relevant electron collisionality of 0.2. The applied field reduces the pedestal density, pressure, and edge current without degrading the edge thermal transport barrier. ELITE calculations find the resulting profiles are stable to intermediate-n peeling-ballooning modes. ELM suppression is demonstrated using different upper and lower phases enabling new investigations into the necessary conditions for suppression in terms of the resonant field amplitude and $q_{95}$.

Authors

M.J. Lanctot

Lawrence Livermore National Laboratory
M.E. Fenstermacher

Lawrence Livermore National Laboratory, LLNL
I. Joseph

Lawrence Livermore Natl. Lab., LLNL, Lawrence Livermore National Lab, Lawrence Livermore National Laboratory
R.J. Buttery

General Atomics
M.R. Wade

General Atomics
T.E. Evans

General Atomics
N.M. Ferraro

General Atomics
J.S. deGrassie

General Atomics
Philip Snyder

GA, General Atomics
R. Nazikian

Princeton Plasma Physics Laboratory, PPPL
R.A. Moyer

UCSD, University of California San Diego
D.M. Orlov

UCSD, University of California San Diego
J.M. Hanson

Columbia University, Columbia U.
W. Suttrop

IPP-EURATOM
S. Haskey

Australia National University