Shafranov shift bifurcation of turbulent transport in the high βp scenario on DIII-D

J. McClenaghan; A. M. Garofalo; G. M. Staebler; S. Y. Ding; X. Gong; J. Qian; J. Huang

doi:10.1088/1741-4326/ab4086

Shafranov shift bifurcation of turbulent transport in the high β_p scenario on DIII-D

J. McClenaghan, A. M. Garofalo, G. M. Staebler, S. Y. Ding, X. Gong, J. Qian, J. Huang

Fusion Theory and Modeling

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19 Scopus citations

Abstract

Shafranov shift stabilization of turbulence creates a bifurcation in transport, leading to multiple confinement states in the high β_p scenario on DIII-D: an H-mode confinement state with a high edge pedestal, and an enhanced confinement state with a low pedestal and an internal transport barrier (ITB). The bifurcation is observed experimentally in the ion energy transport with respect to mid-radius (ρ = 0.6) pressure gradient. Simultaneously, the electron transport exhibits a similar but less dramatic behavior with respect to pressure gradient. The Shafranov shift is found to increase at the same time as the transition to enhanced confinement, and quasilinear gyro-Landau fluid modeling shows a reduction of predicted energy flux consistent on-set of the ITB. Transient perturbations such as ELMs are likely a trigger for the transition between states by lowering the edge pressure and increasing mid-radius pressure gradient.

Original language	English
Article number	124002
Journal	Nuclear Fusion
Volume	59
Issue number	12
DOIs	https://doi.org/10.1088/1741-4326/ab4086
State	Published - Sep 20 2019

Keywords

Bifurcation
High β
Shafranov shift
Transport

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10.1088/1741-4326/ab4086

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title = "Shafranov shift bifurcation of turbulent transport in the high βp scenario on DIII-D",

abstract = "Shafranov shift stabilization of turbulence creates a bifurcation in transport, leading to multiple confinement states in the high βp scenario on DIII-D: an H-mode confinement state with a high edge pedestal, and an enhanced confinement state with a low pedestal and an internal transport barrier (ITB). The bifurcation is observed experimentally in the ion energy transport with respect to mid-radius (ρ = 0.6) pressure gradient. Simultaneously, the electron transport exhibits a similar but less dramatic behavior with respect to pressure gradient. The Shafranov shift is found to increase at the same time as the transition to enhanced confinement, and quasilinear gyro-Landau fluid modeling shows a reduction of predicted energy flux consistent on-set of the ITB. Transient perturbations such as ELMs are likely a trigger for the transition between states by lowering the edge pressure and increasing mid-radius pressure gradient.",

keywords = "Bifurcation, High β, Shafranov shift, Transport",

author = "J. McClenaghan and Garofalo, \{A. M.\} and Staebler, \{G. M.\} and Ding, \{S. Y.\} and X. Gong and J. Qian and J. Huang",

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doi = "10.1088/1741-4326/ab4086",

language = "English",

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T1 - Shafranov shift bifurcation of turbulent transport in the high βp scenario on DIII-D

AU - McClenaghan, J.

AU - Garofalo, A. M.

AU - Staebler, G. M.

AU - Ding, S. Y.

AU - Gong, X.

AU - Qian, J.

AU - Huang, J.

PY - 2019/9/20

Y1 - 2019/9/20

N2 - Shafranov shift stabilization of turbulence creates a bifurcation in transport, leading to multiple confinement states in the high βp scenario on DIII-D: an H-mode confinement state with a high edge pedestal, and an enhanced confinement state with a low pedestal and an internal transport barrier (ITB). The bifurcation is observed experimentally in the ion energy transport with respect to mid-radius (ρ = 0.6) pressure gradient. Simultaneously, the electron transport exhibits a similar but less dramatic behavior with respect to pressure gradient. The Shafranov shift is found to increase at the same time as the transition to enhanced confinement, and quasilinear gyro-Landau fluid modeling shows a reduction of predicted energy flux consistent on-set of the ITB. Transient perturbations such as ELMs are likely a trigger for the transition between states by lowering the edge pressure and increasing mid-radius pressure gradient.

AB - Shafranov shift stabilization of turbulence creates a bifurcation in transport, leading to multiple confinement states in the high βp scenario on DIII-D: an H-mode confinement state with a high edge pedestal, and an enhanced confinement state with a low pedestal and an internal transport barrier (ITB). The bifurcation is observed experimentally in the ion energy transport with respect to mid-radius (ρ = 0.6) pressure gradient. Simultaneously, the electron transport exhibits a similar but less dramatic behavior with respect to pressure gradient. The Shafranov shift is found to increase at the same time as the transition to enhanced confinement, and quasilinear gyro-Landau fluid modeling shows a reduction of predicted energy flux consistent on-set of the ITB. Transient perturbations such as ELMs are likely a trigger for the transition between states by lowering the edge pressure and increasing mid-radius pressure gradient.

KW - Bifurcation

KW - High β

KW - Shafranov shift

KW - Transport

UR - https://www.scopus.com/pages/publications/85076734832

U2 - 10.1088/1741-4326/ab4086

DO - 10.1088/1741-4326/ab4086

M3 - Article

AN - SCOPUS:85076734832

SN - 0029-5515

VL - 59

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 12

M1 - 124002

ER -

Shafranov shift bifurcation of turbulent transport in the high β_p scenario on DIII-D

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Keywords

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