Exploration of the Super H-mode regime on DIII-D and potential advantages for burning plasma devices

W. M. Solomon; P. B. Snyder; A. Bortolon; K. H. Burrell; A. M. Garofalo; B. A. Grierson; R. J. Groebner; A. Loarte; A. W. Leonard; O. Meneghini; R. Nazikian; T. H. Osborne; C. C. Petty; F. Poli

doi:10.1063/1.4944822

Exploration of the Super H-mode regime on DIII-D and potential advantages for burning plasma devices

W. M. Solomon
, P. B. Snyder
, A. Bortolon
, K. H. Burrell
, A. M. Garofalo
, B. A. Grierson
, R. J. Groebner
, A. Loarte
, A. W. Leonard
, O. Meneghini
, R. Nazikian
, T. H. Osborne
, C. C. Petty
, F. Poli

PPPL Tokamak Expermntl Science

Research output: Contribution to journal › Article › peer-review

24 Scopus citations

Abstract

A new high pedestal regime ("Super H-mode") has been predicted and accessed on DIII-D. Super H-mode was first achieved on DIII-D using a quiescent H-mode edge, enabling a smooth trajectory through pedestal parameter space. By exploiting Super H-mode, it has been possible to access high pedestal pressures at high normalized densities. While elimination of Edge localized modes (ELMs) is beneficial for Super H-mode, it may not be a requirement, as recent experiments have maintained high pedestals with ELMs triggered by lithium granule injection. Simulations using TGLF for core transport and the EPED model for the pedestal find that ITER can benefit from the improved performance associated with Super H-mode, with increased values of fusion power and gain possible. Similar studies demonstrate that the Super H-mode pedestal can be advantageous for a steady-state power plant, by providing a path to increasing the bootstrap current while simultaneously reducing the demands on the core physics performance.

Original language	English (US)
Article number	056105
Journal	Physics of Plasmas
Volume	23
Issue number	5
DOIs	https://doi.org/10.1063/1.4944822
State	Published - May 2016

All Science Journal Classification (ASJC) codes

Condensed Matter Physics

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10.1063/1.4944822

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Solomon, W. M., Snyder, P. B., Bortolon, A., Burrell, K. H., Garofalo, A. M., Grierson, B. A., Groebner, R. J., Loarte, A., Leonard, A. W., Meneghini, O., Nazikian, R., Osborne, T. H., Petty, C. C., & Poli, F. (2016). Exploration of the Super H-mode regime on DIII-D and potential advantages for burning plasma devices. Physics of Plasmas, 23(5), Article 056105. https://doi.org/10.1063/1.4944822

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title = "Exploration of the Super H-mode regime on DIII-D and potential advantages for burning plasma devices",

abstract = "A new high pedestal regime ({"}Super H-mode{"}) has been predicted and accessed on DIII-D. Super H-mode was first achieved on DIII-D using a quiescent H-mode edge, enabling a smooth trajectory through pedestal parameter space. By exploiting Super H-mode, it has been possible to access high pedestal pressures at high normalized densities. While elimination of Edge localized modes (ELMs) is beneficial for Super H-mode, it may not be a requirement, as recent experiments have maintained high pedestals with ELMs triggered by lithium granule injection. Simulations using TGLF for core transport and the EPED model for the pedestal find that ITER can benefit from the improved performance associated with Super H-mode, with increased values of fusion power and gain possible. Similar studies demonstrate that the Super H-mode pedestal can be advantageous for a steady-state power plant, by providing a path to increasing the bootstrap current while simultaneously reducing the demands on the core physics performance.",

author = "Solomon, \{W. M.\} and Snyder, \{P. B.\} and A. Bortolon and Burrell, \{K. H.\} and Garofalo, \{A. M.\} and Grierson, \{B. A.\} and Groebner, \{R. J.\} and A. Loarte and Leonard, \{A. W.\} and O. Meneghini and R. Nazikian and Osborne, \{T. H.\} and Petty, \{C. C.\} and F. Poli",

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doi = "10.1063/1.4944822",

language = "English (US)",

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AU - Snyder, P. B.

AU - Bortolon, A.

AU - Burrell, K. H.

AU - Garofalo, A. M.

AU - Grierson, B. A.

AU - Groebner, R. J.

AU - Loarte, A.

AU - Leonard, A. W.

AU - Meneghini, O.

AU - Nazikian, R.

AU - Osborne, T. H.

AU - Petty, C. C.

AU - Poli, F.

PY - 2016/5

Y1 - 2016/5

N2 - A new high pedestal regime ("Super H-mode") has been predicted and accessed on DIII-D. Super H-mode was first achieved on DIII-D using a quiescent H-mode edge, enabling a smooth trajectory through pedestal parameter space. By exploiting Super H-mode, it has been possible to access high pedestal pressures at high normalized densities. While elimination of Edge localized modes (ELMs) is beneficial for Super H-mode, it may not be a requirement, as recent experiments have maintained high pedestals with ELMs triggered by lithium granule injection. Simulations using TGLF for core transport and the EPED model for the pedestal find that ITER can benefit from the improved performance associated with Super H-mode, with increased values of fusion power and gain possible. Similar studies demonstrate that the Super H-mode pedestal can be advantageous for a steady-state power plant, by providing a path to increasing the bootstrap current while simultaneously reducing the demands on the core physics performance.

AB - A new high pedestal regime ("Super H-mode") has been predicted and accessed on DIII-D. Super H-mode was first achieved on DIII-D using a quiescent H-mode edge, enabling a smooth trajectory through pedestal parameter space. By exploiting Super H-mode, it has been possible to access high pedestal pressures at high normalized densities. While elimination of Edge localized modes (ELMs) is beneficial for Super H-mode, it may not be a requirement, as recent experiments have maintained high pedestals with ELMs triggered by lithium granule injection. Simulations using TGLF for core transport and the EPED model for the pedestal find that ITER can benefit from the improved performance associated with Super H-mode, with increased values of fusion power and gain possible. Similar studies demonstrate that the Super H-mode pedestal can be advantageous for a steady-state power plant, by providing a path to increasing the bootstrap current while simultaneously reducing the demands on the core physics performance.

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Exploration of the Super H-mode regime on DIII-D and potential advantages for burning plasma devices

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