Erosion estimates for the divertor and main wall components from STEP

Kirschner, A.; Henderson, S.S.; Brezinsek, S.; Romazanov, J.; Kovari, M.; Baumann, C.; Linsmeier, Ch.; Flynn, E.; Hess, J.; Osawa, R.T.; Newton, S.L.; Moulton, D.; ,

doi:10.1088/1741-4326/ad067d

Nucl. Fusion

2023

DOI: 10.1088/1741-4326/ad067d

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Erosion estimates for the divertor and main wall components from STEP

A. Kirschner,

S.S. Henderson,

S. Brezinsek

et al.

Abstract: The tungsten erosion within STEP assuming tungsten main wall and tungsten divertor has been estimated with ERO at the inner and outer divertor, at the inner and outer midplane and at the outboard baffle entrance. Plasma parameters are based on SOLPS simulations applying argon puffing for edge cooling. The plasma parameter range covers peak electron temperatures Te between 3 and 25 eV in the divertor. At the inner midplane Te ~ 13 eV, at the outer midplane ~ 7eV and at the outboard baffle entrance between 1 eV … Show more

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2024

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Cited by 2 publications

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Assessment of the impact of fuelling puff location on divertor impurity compression and enrichment in STEP

Osawa,

Newton,

Moulton

et al. 2024

Nucl. Fusion

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In order to achieve a compatible solution between the divertors and the core, SOLPS-ITER simulations were performed in a STEP (Spherical Tokamak for Energy Production) connected double-null geometry to investigate the possibility of using deuterium (D2 ) puff locations as an actuator for divertor argon (Ar) compression/enrichment. It was found that puffing D2 from the inner-midplane (IMP) D2 puff enhanced Ar compression and enrichment on the high-field-side (HFS) and lowered the required upstream Ar fraction to achieve acceptable target conditions. An interesting link was found between the argon compression and the number of stagnation points of the middle-charge-state Ar ions in the HFS SOL, Nst ; significantly improved compression and enrichment were obtained for Nst = 1 (corresponding mostly to the cases with IMP puff) compared to Nst = 3 (corresponding mostly to the cases without IMP puff). An intermediate compression and enrichment was obtained when Nst = 5. The change of Nst from 3 to 1 (or 5) was achieved by a combination of D+ outflow, high collision frequency, and flipped temperature gradients around the IMP. Given a possible drawback of ΓOMP+IMP D , that is, a direct effect on the upstream main plasma density and temperature, we propose ΓPFR+IMP D as the best solution, balancing the negative and positive effects of PFR and IMP D2 puffs. Further studies will be carried out both experimentally and numerically.

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Assessment of the impact of fuelling puff location on divertor impurity compression and enrichment in STEP

Osawa,

Newton,

Moulton

et al. 2024

Nucl. Fusion

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Managing the heat: In-Vessel Components

Cane,

Barth,

Farrington

et al. 2024

Phil. Trans. R. Soc. A.

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The Spherical Tokamak for Energy Production (STEP) programme aims to deliver a first-of-a-kind fusion prototype powerplant (SPP). The SPP plasma places extreme heat, particle and structural loads onto the plasma-facing components (PFCs) of the divertor, limiters and inboard and outboard sections of the first wall. The PFCs must manage the heat and particle loads and wider powerplant requirements relating to safety, net power generation, tritium breeding and plant availability. To enable STEP PFC concepts to be identified that satisfy these wide-ranging requirements, an iterative design (‘Decide & Iterate’) methodology has been used to synchronize a prioritized set of decisions, within the fast-paced, iterative, whole plant concept design schedule. This paper details the ‘Decide and Iterate’ methodology and explains how it has enabled the identification of the SPP PFC concepts. These include innovative PFC solutions such as a helium-cooled discrete and panel limiter design to increase tritium breeding while providing sufficient coverage and enabling individual limiter replacement; the integration of the outboard first wall with the breeding zone to enhance fuel self-sufficiency and power generation; and the use of heavy water (D 2 O) within the inboard first wall and divertor PFCs to increase tritium breeding within the outboard breeding zone. This article is part of the theme issue ‘Delivering Fusion Energy – The Spherical Tokamak for Energy Production (STEP)’.

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Erosion estimates for the divertor and main wall components from STEP

Cited by 2 publications

References 37 publications

Assessment of the impact of fuelling puff location on divertor impurity compression and enrichment in STEP

Assessment of the impact of fuelling puff location on divertor impurity compression and enrichment in STEP

Managing the heat: In-Vessel Components

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