Investigation of energy transport in DIII-D High-βP EAST-demonstration discharges with the TGLF turbulent and NEO neoclassical transport models

C. Pan; G. M. Staebler; L. L. Lao; A. M. Garofalo; X. Gong; Q. Ren; J. McClenaghan; G. Li; S. Ding; J. Qian; B. Wan; G. S. Xu; W. Solomon; O. Meneghini; S. P. Smith

doi:10.1088/1741-4326/aa4ff8

Investigation of energy transport in DIII-D High-β_P EAST-demonstration discharges with the TGLF turbulent and NEO neoclassical transport models

C. Pan, G. M. Staebler, L. L. Lao, A. M. Garofalo, X. Gong, Q. Ren, J. McClenaghan, G. Li, S. Ding, J. Qian, B. Wan, G. S. Xu, W. Solomon, O. Meneghini, S. P. Smith

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43 Scopus citations

Abstract

Energy transport analyses of the DIII-D high-β_P EAST-demonstration discharges have been performed using the TGYRO transport package with the TGLF turbulent and NEO neoclassical transport models under the OMFIT integrated modeling framework. Ion energy transport is shown to be dominated by neoclassical transport and ion temperature profiles predicted by TGYRO agree closely with the experimental measured profiles for these high-β_P discharges. Ion energy transport is largely insensitive to reductions in the E × B flow shear stabilization. The Shafranov shift is shown to play a role in the suppression of the ion turbulent energy transport below the neoclassical level. Electron turbulent energy transport is under-predicted by TGLF and a significant shortfall in the electron energy transport over the whole core plasma is found with TGLF predictions for these high-β_P discharges. TGYRO can successfully predict the experimental ion and electron temperature profiles by artificially increasing the saturated turbulence level for ETG driven modes used in TGLF.

Original language	English
Article number	036018
Journal	Nuclear Fusion
Volume	57
Issue number	3
DOIs	https://doi.org/10.1088/1741-4326/aa4ff8
State	Published - Mar 2017
Externally published	Yes

Funding

This work was supported by US DOE under DE-FC02-04ER54698 and DE-FG03-95ER54309, the National Natural Science Foundation of China under Grant Nos. 11575246, 11105182, 11422546, 11575235 and the National Magnetic Confinement Fusion Program of China under Contract No. 2014GB106001, 2015GB101000, No. 2015GB102001 and No. 2015GB110001.

Keywords

EXB
Shafranov shif
energy transport
high-β

Access to Document

10.1088/1741-4326/aa4ff8

Cite this

Pan, C., Staebler, G. M., Lao, L. L., Garofalo, A. M., Gong, X., Ren, Q., McClenaghan, J., Li, G., Ding, S., Qian, J., Wan, B., Xu, G. S., Solomon, W., Meneghini, O., & Smith, S. P. (2017). Investigation of energy transport in DIII-D High-β_P EAST-demonstration discharges with the TGLF turbulent and NEO neoclassical transport models. Nuclear Fusion, 57(3), Article 036018. https://doi.org/10.1088/1741-4326/aa4ff8

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title = "Investigation of energy transport in DIII-D High-βP EAST-demonstration discharges with the TGLF turbulent and NEO neoclassical transport models",

abstract = "Energy transport analyses of the DIII-D high-βP EAST-demonstration discharges have been performed using the TGYRO transport package with the TGLF turbulent and NEO neoclassical transport models under the OMFIT integrated modeling framework. Ion energy transport is shown to be dominated by neoclassical transport and ion temperature profiles predicted by TGYRO agree closely with the experimental measured profiles for these high-βP discharges. Ion energy transport is largely insensitive to reductions in the E × B flow shear stabilization. The Shafranov shift is shown to play a role in the suppression of the ion turbulent energy transport below the neoclassical level. Electron turbulent energy transport is under-predicted by TGLF and a significant shortfall in the electron energy transport over the whole core plasma is found with TGLF predictions for these high-βP discharges. TGYRO can successfully predict the experimental ion and electron temperature profiles by artificially increasing the saturated turbulence level for ETG driven modes used in TGLF.",

keywords = "EXB, Shafranov shif, energy transport, high-β",

author = "C. Pan and Staebler, {G. M.} and Lao, {L. L.} and Garofalo, {A. M.} and X. Gong and Q. Ren and J. McClenaghan and G. Li and S. Ding and J. Qian and B. Wan and Xu, {G. S.} and W. Solomon and O. Meneghini and Smith, {S. P.}",

note = "Publisher Copyright: {\textcopyright} 2017 IAEA.",

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Pan, C, Staebler, GM, Lao, LL, Garofalo, AM, Gong, X, Ren, Q, McClenaghan, J, Li, G, Ding, S, Qian, J, Wan, B, Xu, GS, Solomon, W, Meneghini, O & Smith, SP 2017, 'Investigation of energy transport in DIII-D High-β_P EAST-demonstration discharges with the TGLF turbulent and NEO neoclassical transport models', Nuclear Fusion, vol. 57, no. 3, 036018. https://doi.org/10.1088/1741-4326/aa4ff8

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AU - Pan, C.

AU - Staebler, G. M.

AU - Lao, L. L.

AU - Garofalo, A. M.

AU - Gong, X.

AU - Ren, Q.

AU - McClenaghan, J.

AU - Li, G.

AU - Ding, S.

AU - Qian, J.

AU - Wan, B.

AU - Xu, G. S.

AU - Solomon, W.

AU - Meneghini, O.

AU - Smith, S. P.

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N2 - Energy transport analyses of the DIII-D high-βP EAST-demonstration discharges have been performed using the TGYRO transport package with the TGLF turbulent and NEO neoclassical transport models under the OMFIT integrated modeling framework. Ion energy transport is shown to be dominated by neoclassical transport and ion temperature profiles predicted by TGYRO agree closely with the experimental measured profiles for these high-βP discharges. Ion energy transport is largely insensitive to reductions in the E × B flow shear stabilization. The Shafranov shift is shown to play a role in the suppression of the ion turbulent energy transport below the neoclassical level. Electron turbulent energy transport is under-predicted by TGLF and a significant shortfall in the electron energy transport over the whole core plasma is found with TGLF predictions for these high-βP discharges. TGYRO can successfully predict the experimental ion and electron temperature profiles by artificially increasing the saturated turbulence level for ETG driven modes used in TGLF.

AB - Energy transport analyses of the DIII-D high-βP EAST-demonstration discharges have been performed using the TGYRO transport package with the TGLF turbulent and NEO neoclassical transport models under the OMFIT integrated modeling framework. Ion energy transport is shown to be dominated by neoclassical transport and ion temperature profiles predicted by TGYRO agree closely with the experimental measured profiles for these high-βP discharges. Ion energy transport is largely insensitive to reductions in the E × B flow shear stabilization. The Shafranov shift is shown to play a role in the suppression of the ion turbulent energy transport below the neoclassical level. Electron turbulent energy transport is under-predicted by TGLF and a significant shortfall in the electron energy transport over the whole core plasma is found with TGLF predictions for these high-βP discharges. TGYRO can successfully predict the experimental ion and electron temperature profiles by artificially increasing the saturated turbulence level for ETG driven modes used in TGLF.

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