Nuclear Fusion (Jan 2024)

Inter-ELM pedestal turbulence dynamics dependence on q95 and temperature gradient

  • Z. Yan,
  • G.R. McKee,
  • J. Xia,
  • X. Jian,
  • R. Groebner,
  • T. Rhodes,
  • K. Barada,
  • S. Haskey,
  • J. Chen,
  • S. Banerjee,
  • F. Laggner,
  • the DIII-D Team

DOI
https://doi.org/10.1088/1741-4326/ad536a
Journal volume & issue
Vol. 64, no. 9
p. 096001

Abstract

Read online

A series of dedicated experiments from the DIII-D tokamak provide spatially and temporally resolved measurements of electron density and temperature, and multiscale and multichannel fluctuations over a wide range of conditions. Measurements of long wavelength density fluctuations in the type-I ELMing H-mode pedestals routinely reveal a coexistence of multiple instabilities that exhibit dramatic different dynamic behaviors as q _95 and temperature gradients are varied, apparently responsible for limiting pedestal temperature profiles. Two distinct frequency bands of density fluctuations are modulated by an ELM cycle with frequency above 200 kHz propagating in the electron diamagnetic direction in the lab frame (electron mode) and below 200 kHz propagating in the ion diamagnetic direction (ion mode). The electron mode amplitude peaks near the electron temperature gradient region and increases with q _95 which seems to be correlated with the increased χ _e at higher q _95 , similar to the characteristics expected for the micro-tearing mode (MTM). At higher q _95 , during the inter-ELM period, the ion mode decays at the later phase of the ELM cycle. Consistently, the poloidal correlation length of the ion mode is also found to reduce, which suggests the possible E × B flow shear suppression of the ion mode at the later phase of the ELM cycle as the E _r well recovers. In contrast, the electron mode grows during the ELM cycle and reaches saturation at around 50%–60% of the ELM period. Linear gyrokinetic simulations find the MTMs to be the most unstable mode in the pedestal electron temperature gradient region. The higher q _95 and lower magnetic shear destabilize the MTMs. These observations provide key insights into the underlying physics of multifield properties and a rich dataset of experimental ‘fingerprints’ that enable new tests of theoretical pedestal models and lead to the development of a predictive model for pedestal formation on the ITER and future burning plasma experiments.

Keywords