First tungsten radiation studies in DIII-D’s ITER baseline demonstration discharges

F. Turco; T. C. Luce; A. Sips; C. Greenfield; T. Osborne; T. Odstrcil; J. M. Hanson; A. McLean; A. Hyatt

doi:10.1088/1741-4326/ad536b

First tungsten radiation studies in DIII-D’s ITER baseline demonstration discharges

F. Turco, T. C. Luce, A. Sips, C. Greenfield, T. Osborne, T. Odstrcil, J. M. Hanson, A. McLean, A. Hyatt

Fusion Energy Division

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

3 Scopus citations

Abstract

ITER Baseline Scenario plasmas were studied in DIII-D using krypton and xenon gases as a proxy for the tungsten that will be present in ITER. These impurities were chosen for having the same radiative loss rate Lz as tungsten would exhibit in the hotter ITER core. Results show that the scenario with these core radiators spans the range of impurity concentration and W radiated fraction expected for ITER, and up to 50% higher values, explored at zero injected torque, as well as 1 Nm and full co-torque injection with T ∼ 3 Nm. Stationary discharges with duration >2-4 τ_R are achieved with f _rad ⩾ 30% leading to a reduction in confinement of ∼10%, and a comparison with real metal radiators in the same range of f _rad shows that the higher Lz at the lower temperatures in these plasmas yields too pessimistic results on the survivability and performance of this scenario in ITER. Simulations of ITER power balance including W radiation show that with concentration up to three times higher than in the DIII-D plasmas the scenario can be stationary, remaining at acceptable core radiated fraction values.

Original language	English
Article number	076063
Journal	Nuclear Fusion
Volume	64
Issue number	7
DOIs	https://doi.org/10.1088/1741-4326/ad536b
State	Published - Jul 2024

Funding

This material is based upon work supported by the U.S. Department of Energy, Office of Science, Office of Fusion Energy Sciences, using the DIII-D National Fusion Facility, a DOE Office of Science user facility, under Award(s) DE-FG02-04ER54761, DE-FC02-04ER54698, DE-AC52-07NA27344. This report was prepared as an account of work sponsored by an agency of the United States Government. Neither the United States Government nor any agency thereof, nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, trademark, manufacturer, or otherwise does not necessarily constitute or imply its endorsement, recommendation, or favoring by the United States Government or any agency thereof. The views and opinions of authors expressed herein do not necessarily state or reflect those of the United States Government or any agency thereof. The authors would like to thank Thomas Pütterich for providing the filtered atomic data for SXR radiation.

Keywords

ITER baseline scenario
integrated scenarios
tungsten radiation

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10.1088/1741-4326/ad536b

Cite this

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title = "First tungsten radiation studies in DIII-D{\textquoteright}s ITER baseline demonstration discharges",

abstract = "ITER Baseline Scenario plasmas were studied in DIII-D using krypton and xenon gases as a proxy for the tungsten that will be present in ITER. These impurities were chosen for having the same radiative loss rate Lz as tungsten would exhibit in the hotter ITER core. Results show that the scenario with these core radiators spans the range of impurity concentration and W radiated fraction expected for ITER, and up to 50\% higher values, explored at zero injected torque, as well as 1 Nm and full co-torque injection with T ∼ 3 Nm. Stationary discharges with duration >2-4 τR are achieved with f rad ⩾ 30\% leading to a reduction in confinement of ∼10\%, and a comparison with real metal radiators in the same range of f rad shows that the higher Lz at the lower temperatures in these plasmas yields too pessimistic results on the survivability and performance of this scenario in ITER. Simulations of ITER power balance including W radiation show that with concentration up to three times higher than in the DIII-D plasmas the scenario can be stationary, remaining at acceptable core radiated fraction values.",

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author = "F. Turco and Luce, \{T. C.\} and A. Sips and C. Greenfield and T. Osborne and T. Odstrcil and Hanson, \{J. M.\} and A. McLean and A. Hyatt",

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language = "English",

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T1 - First tungsten radiation studies in DIII-D’s ITER baseline demonstration discharges

AU - Turco, F.

AU - Luce, T. C.

AU - Sips, A.

AU - Greenfield, C.

AU - Osborne, T.

AU - Odstrcil, T.

AU - Hanson, J. M.

AU - McLean, A.

AU - Hyatt, A.

PY - 2024/7

Y1 - 2024/7

N2 - ITER Baseline Scenario plasmas were studied in DIII-D using krypton and xenon gases as a proxy for the tungsten that will be present in ITER. These impurities were chosen for having the same radiative loss rate Lz as tungsten would exhibit in the hotter ITER core. Results show that the scenario with these core radiators spans the range of impurity concentration and W radiated fraction expected for ITER, and up to 50% higher values, explored at zero injected torque, as well as 1 Nm and full co-torque injection with T ∼ 3 Nm. Stationary discharges with duration >2-4 τR are achieved with f rad ⩾ 30% leading to a reduction in confinement of ∼10%, and a comparison with real metal radiators in the same range of f rad shows that the higher Lz at the lower temperatures in these plasmas yields too pessimistic results on the survivability and performance of this scenario in ITER. Simulations of ITER power balance including W radiation show that with concentration up to three times higher than in the DIII-D plasmas the scenario can be stationary, remaining at acceptable core radiated fraction values.

AB - ITER Baseline Scenario plasmas were studied in DIII-D using krypton and xenon gases as a proxy for the tungsten that will be present in ITER. These impurities were chosen for having the same radiative loss rate Lz as tungsten would exhibit in the hotter ITER core. Results show that the scenario with these core radiators spans the range of impurity concentration and W radiated fraction expected for ITER, and up to 50% higher values, explored at zero injected torque, as well as 1 Nm and full co-torque injection with T ∼ 3 Nm. Stationary discharges with duration >2-4 τR are achieved with f rad ⩾ 30% leading to a reduction in confinement of ∼10%, and a comparison with real metal radiators in the same range of f rad shows that the higher Lz at the lower temperatures in these plasmas yields too pessimistic results on the survivability and performance of this scenario in ITER. Simulations of ITER power balance including W radiation show that with concentration up to three times higher than in the DIII-D plasmas the scenario can be stationary, remaining at acceptable core radiated fraction values.

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KW - tungsten radiation

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M3 - Article

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JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 7

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ER -

First tungsten radiation studies in DIII-D’s ITER baseline demonstration discharges

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