Initial TCV operation with a baffled divertor

the TCV Team; EUROFusion MST Team

doi:10.1088/1741-4326/abd196

Initial TCV operation with a baffled divertor

the TCV Team, EUROFusion MST Team

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

37 Scopus citations

Abstract

The Tokamak à Configuration Variable (TCV) tokamak is in the midst of an upgrade to further its capability to investigate conventional and alternative divertor configurations. To that end, modular and removable gas baffles have been installed to decrease the coupling between the divertor and the plasma core. The baffles primarily seek to suppress the transit of recycling neutrals to closed flux surfaces. A first experimental campaign with the gas baffles has shown that the baffled divertor remains compatible with a wide range of configurations including snowflake and super-X divertors. Plasma density ramp experiments reveal an increase of the neutral pressure in the divertor by up to a factor ×5 compared to the unbaffled divertor and thereby qualitatively confirm simulations with the SOLPS-ITER code that were used to guide the baffle design. Together with a range of new and upgraded divertor diagnostics, the baffled TCV divertor is now used to validate divertor models for ITER and next step devices with particular emphasis on geometric variations.

Original language	English
Article number	024002
Journal	Nuclear Fusion
Volume	61
Issue number	2
DOIs	https://doi.org/10.1088/1741-4326/abd196
State	Published - Feb 2021
Externally published	Yes

Keywords

Divertor
Plasma exhaust
TCV tokamak

Access to Document

10.1088/1741-4326/abd196

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title = "Initial TCV operation with a baffled divertor",

abstract = "The Tokamak {\`a} Configuration Variable (TCV) tokamak is in the midst of an upgrade to further its capability to investigate conventional and alternative divertor configurations. To that end, modular and removable gas baffles have been installed to decrease the coupling between the divertor and the plasma core. The baffles primarily seek to suppress the transit of recycling neutrals to closed flux surfaces. A first experimental campaign with the gas baffles has shown that the baffled divertor remains compatible with a wide range of configurations including snowflake and super-X divertors. Plasma density ramp experiments reveal an increase of the neutral pressure in the divertor by up to a factor ×5 compared to the unbaffled divertor and thereby qualitatively confirm simulations with the SOLPS-ITER code that were used to guide the baffle design. Together with a range of new and upgraded divertor diagnostics, the baffled TCV divertor is now used to validate divertor models for ITER and next step devices with particular emphasis on geometric variations.",

keywords = "Divertor, Plasma exhaust, TCV tokamak",

author = "{the TCV Team} and {EUROFusion MST Team} and H. Reimerdes and Duval, {B. P.} and H. Elaian and A. Fasoli and O. F{\'e}vrier and C. Theiler and F. Bagnato and M. Baquero-Ruiz and P. Blanchard and D. Brida and C. Colandrea and {de Oliveira}, H. and D. Galassi and S. Gorno and S. Henderson and M. Komm and B. Linehan and L. Martinelli and R. Maurizio and Moret, {J. M.} and A. Perek and H. Raj and U. Sheikh and D. Testa and M. Toussaint and Tsui, {C. K.} and M. Wensing",

note = "Publisher Copyright: {\textcopyright} 2021 EURATOM.",

year = "2021",

month = feb,

doi = "10.1088/1741-4326/abd196",

language = "English",

volume = "61",

journal = "Nuclear Fusion",

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AU - the TCV Team

AU - EUROFusion MST Team

AU - Reimerdes, H.

AU - Duval, B. P.

AU - Elaian, H.

AU - Fasoli, A.

AU - Février, O.

AU - Theiler, C.

AU - Bagnato, F.

AU - Baquero-Ruiz, M.

AU - Blanchard, P.

AU - Brida, D.

AU - Colandrea, C.

AU - de Oliveira, H.

AU - Galassi, D.

AU - Gorno, S.

AU - Henderson, S.

AU - Komm, M.

AU - Linehan, B.

AU - Martinelli, L.

AU - Maurizio, R.

AU - Moret, J. M.

AU - Perek, A.

AU - Raj, H.

AU - Sheikh, U.

AU - Testa, D.

AU - Toussaint, M.

AU - Tsui, C. K.

AU - Wensing, M.

PY - 2021/2

Y1 - 2021/2

N2 - The Tokamak à Configuration Variable (TCV) tokamak is in the midst of an upgrade to further its capability to investigate conventional and alternative divertor configurations. To that end, modular and removable gas baffles have been installed to decrease the coupling between the divertor and the plasma core. The baffles primarily seek to suppress the transit of recycling neutrals to closed flux surfaces. A first experimental campaign with the gas baffles has shown that the baffled divertor remains compatible with a wide range of configurations including snowflake and super-X divertors. Plasma density ramp experiments reveal an increase of the neutral pressure in the divertor by up to a factor ×5 compared to the unbaffled divertor and thereby qualitatively confirm simulations with the SOLPS-ITER code that were used to guide the baffle design. Together with a range of new and upgraded divertor diagnostics, the baffled TCV divertor is now used to validate divertor models for ITER and next step devices with particular emphasis on geometric variations.

AB - The Tokamak à Configuration Variable (TCV) tokamak is in the midst of an upgrade to further its capability to investigate conventional and alternative divertor configurations. To that end, modular and removable gas baffles have been installed to decrease the coupling between the divertor and the plasma core. The baffles primarily seek to suppress the transit of recycling neutrals to closed flux surfaces. A first experimental campaign with the gas baffles has shown that the baffled divertor remains compatible with a wide range of configurations including snowflake and super-X divertors. Plasma density ramp experiments reveal an increase of the neutral pressure in the divertor by up to a factor ×5 compared to the unbaffled divertor and thereby qualitatively confirm simulations with the SOLPS-ITER code that were used to guide the baffle design. Together with a range of new and upgraded divertor diagnostics, the baffled TCV divertor is now used to validate divertor models for ITER and next step devices with particular emphasis on geometric variations.

KW - Divertor

KW - Plasma exhaust

KW - TCV tokamak

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JO - Nuclear Fusion

JF - Nuclear Fusion

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ER -

Initial TCV operation with a baffled divertor

Abstract

Keywords

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