| Tokamak à configuration variable | |
|---|---|
 TCV in 2002 | |
| Device type | Tokamak |
| Location | Lausanne, Switzerland |
| Affiliation | EPFL Swiss Plasma Center |
| Technical specifications | |
| Major radius | 0.88 m (2 ft 11 in) |
| Minor radius | 0.25 m (9.8 in) |
| Magnetic field | 1.43 T (14,300 G) |
| Heating power | 4.5 MW |
| Discharge duration | 2 s |
| Plasma current | 1.2 MA |
| History | |
| Year(s) of operation | 1992–present |
| Preceded by | TCA (now TCABR) |
The tokamak à configuration variable (TCV, literally "variable configuration tokamak") is an experimental tokamak located at the École Polytechnique Fédérale de Lausanne (EPFL) Swiss Plasma Center (SPC) in Lausanne, Switzerland. As the largest experimental facility of the Swiss Plasma Center, [1] the TCV tokamak explores the physics of magnetic confinement fusion. It distinguishes itself from other tokamaks with its specialized plasma shaping capability, which can produce diverse plasma shapes without requiring hardware modifications.
The research carried out on TCV contributes to the physics understanding for ITER and future fusion power plants such as DEMO. It is currently part of EUROfusion's Medium-Sized Tokamak (MST) programme, [2] alongside ASDEX Upgrade, MAST Upgrade and WEST.
The TCV tokamak produced its first plasma in November 1992 with full tokamak operation starting in June 1993. [3]
Characteristics
Plasma shaping
TCV features a highly elongated, rectangular vacuum vessel and 16 independently powered coils which facilitate development of new plasma configurations. A notable example is the discovery of significantly improved confinement with the negative triangularity shape in the late 1990s. [4] Novel divertor configurations such as the snowflake divertor were also realised and explored on TCV.
ECRH-ECCD system
Auxiliary heating is provided by the electron cyclotron resonance heating (ECRH) system. EC power in X-mode supplied by the X2 (second harmonic) and X3 (third harmonic) gyrotrons can be launched from the side or the top. The system can also support non-inductive plasma current via electron cyclotron current drive (ECCD). TCV is the first machine in world which has reported plasma with full current in ECCD in 2000. [5]
Neutral beam injection system
The neutral beam injection (NBI) system has been operated on TCV from 2015 for direct ion auxiliary heating which facilitates access to plasma regimes with high plasma pressure, a wider range of temperature ratios, and significant fast ion population. [6] TCV currently has two heating neutral beams and a diagnostic neutral beam. The first heating neutral beam injector can provided up to 1.3 MW of heating power.
Removable neutral baffles
TCV features an "open" divertor historically with limited separation between the divertor region and the main plasma. In 2019, TCV began to operate with removable neutral baffles in order to maximise the divertor neutral compression by limiting the transit of recycling neutrals from the wall to the confined plasma. [7] Baffles of different lengths are available, allowing for experimental study of variable divertor closure.
Major research and discoveries
Negative triangularity
It is first demonstrated on TCV that negative triangularity, where the plasma cross-section is shaped as backward D shape pointing to the center, can yield significantly improved confinement. It is particularly attractive because edge-localized modes (ELMs) can be avoided as an inherent ELM-free regime, while a core of high confinement is maintained. This has motivated the DIII-D tokamak in San Diego to installed additional graphite-tile armor to perform dedicated experimental campaign in early 2023.
Advanced divertors
Main studies
- Confinement studies
- confinement as a function of the shape of the plasma (triangular, square or elongated)
- Improvement of the confinement of the core
- Studies on vertically elongated plasmas
- Studies with ECRH and ECCD ( electron cyclotron resonance heating and electron cyclotron current drive) [8]
History
- 1976: First proposal for an elongated tokamak by the "New Swiss Association"
- 1985: Second proposal, with a more elongated tokamak
- 1986: Acceptance of the TCV proposal (Tokamak à Configuration Variable)
- 1992: First plasma discharge
- 1997: World record of plasma elongation (see plasma shaping)
- by August 2015 it has had a 19-month shutdown/upgrade to install its first neutral beam injector. [9]
References
- ^ "Swiss Plasma Center (SPC) | ETH-Board". www.ethrat.ch. Archived from the original on 2020-12-03. Retrieved 2020-12-08.
- ^ "Medium-Sized Tokamaks". EUROfusion. Retrieved 2023-08-19.
- ^ Hofmann, F; Lister, J B; Anton, W; Barry, S; Behn, R; Bernel, S; Besson, G; Buhlmann, F; Chavan, R; Corboz, M; Dutch, M J; Duval, B P; Fasel, D; Favre, A; Franke, S (1994-12-01). "Creation and control of variably shaped plasmas in TCV". Plasma Physics and Controlled Fusion. 36 (12B): B277–B287. doi: 10.1088/0741-3335/36/12B/023. ISSN 0741-3335. S2CID 250759524.
- ^ Pochelon, A; Goodman, T.P; Henderson, M; Angioni, C; Behn, R; Coda, S; Hofmann, F; Hogge, J.-P; Kirneva, N; Martynov, A.A; Moret, J.-M; Pietrzyk, Z.A; Porcelli, F; Reimerdes, H; Rommers, J (November 1999). "Energy confinement and MHD activity in shaped TCV plasmas with localized electron cyclotron heating". Nuclear Fusion. 39 (11Y): 1807–1818. Bibcode: 1999NucFu..39.1807P. doi: 10.1088/0029-5515/39/11Y/321. ISSN 0029-5515. S2CID 250775203.
- ^ Sauter, O.; Henderson, M. A.; Hofmann, F.; Goodman, T.; Alberti, S.; Angioni, C.; Appert, K.; Behn, R.; Blanchard, P.; Bosshard, P.; Chavan, R.; Coda, S.; Duval, B. P.; Fasel, D.; Favre, A. (2000-04-10). "Steady-State Fully Noninductive Current Driven by Electron Cyclotron Waves in a Magnetically Confined Plasma". Physical Review Letters. 84 (15): 3322–3325. Bibcode: 2000PhRvL..84.3322S. doi: 10.1103/PhysRevLett.84.3322. ISSN 0031-9007. PMID 11019080.
- ^ Karpushov, Alexander N.; Bagnato, Filippo; Baquero-Ruiz, Marcelo; Coda, Stefano; Colandrea, Claudia; Dolizy, Frédéric; Dubray, Jérémie; Duval, Basil P.; Fasel, Damien; Fasoli, Ambrogio; Jacquier, Rémy; Lavanchy, Pierre; Marlétaz, Blaise; Martin, Yves; Martinelli, Lorenzo (February 2023). "Upgrade of the neutral beam heating system on the TCV tokamak – second high energy neutral beam". Fusion Engineering and Design. 187: 113384. doi: 10.1016/j.fusengdes.2022.113384.
- ^ Reimerdes, H.; Duval, B.P.; Elaian, H.; Fasoli, A.; Février, O.; Theiler, C.; Bagnato, F.; Baquero-Ruiz, M.; Blanchard, P.; Brida, D.; Colandrea, C.; De Oliveira, H.; Galassi, D.; Gorno, S.; Henderson, S. (2021-02-01). "Initial TCV operation with a baffled divertor". Nuclear Fusion. 61 (2): 024002. Bibcode: 2021NucFu..61b4002R. doi: 10.1088/1741-4326/abd196. hdl: 21.11116/0000-0007-D639-8. ISSN 0029-5515. S2CID 234294126.
- ^ TCV Auxiliary Heating.
- ^ Keeping fusion research on the boil: Three tokamaks and one stellarator. August 2015
External links
-
TCV official site
- TCV Technical data as of Oct 2012
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| Tokamak à configuration variable | |
|---|---|
|
TCV in 2002 | |
| Device type | Tokamak |
| Location | Lausanne, Switzerland |
| Affiliation | EPFL Swiss Plasma Center |
| Technical specifications | |
| Major radius | 0.88 m (2 ft 11 in) |
| Minor radius | 0.25 m (9.8 in) |
| Magnetic field | 1.43 T (14,300 G) |
| Heating power | 4.5 MW |
| Discharge duration | 2 s |
| Plasma current | 1.2 MA |
| History | |
| Year(s) of operation | 1992–present |
| Preceded by | TCA (now TCABR) |
The tokamak à configuration variable (TCV, literally "variable configuration tokamak") is an experimental tokamak located at the École Polytechnique Fédérale de Lausanne (EPFL) Swiss Plasma Center (SPC) in Lausanne, Switzerland. As the largest experimental facility of the Swiss Plasma Center, [1] the TCV tokamak explores the physics of magnetic confinement fusion. It distinguishes itself from other tokamaks with its specialized plasma shaping capability, which can produce diverse plasma shapes without requiring hardware modifications.
The research carried out on TCV contributes to the physics understanding for ITER and future fusion power plants such as DEMO. It is currently part of EUROfusion's Medium-Sized Tokamak (MST) programme, [2] alongside ASDEX Upgrade, MAST Upgrade and WEST.
The TCV tokamak produced its first plasma in November 1992 with full tokamak operation starting in June 1993. [3]
Characteristics
Plasma shaping
TCV features a highly elongated, rectangular vacuum vessel and 16 independently powered coils which facilitate development of new plasma configurations. A notable example is the discovery of significantly improved confinement with the negative triangularity shape in the late 1990s. [4] Novel divertor configurations such as the snowflake divertor were also realised and explored on TCV.
ECRH-ECCD system
Auxiliary heating is provided by the electron cyclotron resonance heating (ECRH) system. EC power in X-mode supplied by the X2 (second harmonic) and X3 (third harmonic) gyrotrons can be launched from the side or the top. The system can also support non-inductive plasma current via electron cyclotron current drive (ECCD). TCV is the first machine in world which has reported plasma with full current in ECCD in 2000. [5]
Neutral beam injection system
The neutral beam injection (NBI) system has been operated on TCV from 2015 for direct ion auxiliary heating which facilitates access to plasma regimes with high plasma pressure, a wider range of temperature ratios, and significant fast ion population. [6] TCV currently has two heating neutral beams and a diagnostic neutral beam. The first heating neutral beam injector can provided up to 1.3 MW of heating power.
Removable neutral baffles
TCV features an "open" divertor historically with limited separation between the divertor region and the main plasma. In 2019, TCV began to operate with removable neutral baffles in order to maximise the divertor neutral compression by limiting the transit of recycling neutrals from the wall to the confined plasma. [7] Baffles of different lengths are available, allowing for experimental study of variable divertor closure.
Major research and discoveries
Negative triangularity
It is first demonstrated on TCV that negative triangularity, where the plasma cross-section is shaped as backward D shape pointing to the center, can yield significantly improved confinement. It is particularly attractive because edge-localized modes (ELMs) can be avoided as an inherent ELM-free regime, while a core of high confinement is maintained. This has motivated the DIII-D tokamak in San Diego to installed additional graphite-tile armor to perform dedicated experimental campaign in early 2023.
Advanced divertors
Main studies
- Confinement studies
- confinement as a function of the shape of the plasma (triangular, square or elongated)
- Improvement of the confinement of the core
- Studies on vertically elongated plasmas
- Studies with ECRH and ECCD ( electron cyclotron resonance heating and electron cyclotron current drive) [8]
History
- 1976: First proposal for an elongated tokamak by the "New Swiss Association"
- 1985: Second proposal, with a more elongated tokamak
- 1986: Acceptance of the TCV proposal (Tokamak à Configuration Variable)
- 1992: First plasma discharge
- 1997: World record of plasma elongation (see plasma shaping)
- by August 2015 it has had a 19-month shutdown/upgrade to install its first neutral beam injector. [9]
References
- ^ "Swiss Plasma Center (SPC) | ETH-Board". www.ethrat.ch. Archived from the original on 2020-12-03. Retrieved 2020-12-08.
- ^ "Medium-Sized Tokamaks". EUROfusion. Retrieved 2023-08-19.
- ^ Hofmann, F; Lister, J B; Anton, W; Barry, S; Behn, R; Bernel, S; Besson, G; Buhlmann, F; Chavan, R; Corboz, M; Dutch, M J; Duval, B P; Fasel, D; Favre, A; Franke, S (1994-12-01). "Creation and control of variably shaped plasmas in TCV". Plasma Physics and Controlled Fusion. 36 (12B): B277–B287. doi: 10.1088/0741-3335/36/12B/023. ISSN 0741-3335. S2CID 250759524.
- ^ Pochelon, A; Goodman, T.P; Henderson, M; Angioni, C; Behn, R; Coda, S; Hofmann, F; Hogge, J.-P; Kirneva, N; Martynov, A.A; Moret, J.-M; Pietrzyk, Z.A; Porcelli, F; Reimerdes, H; Rommers, J (November 1999). "Energy confinement and MHD activity in shaped TCV plasmas with localized electron cyclotron heating". Nuclear Fusion. 39 (11Y): 1807–1818. Bibcode: 1999NucFu..39.1807P. doi: 10.1088/0029-5515/39/11Y/321. ISSN 0029-5515. S2CID 250775203.
- ^ Sauter, O.; Henderson, M. A.; Hofmann, F.; Goodman, T.; Alberti, S.; Angioni, C.; Appert, K.; Behn, R.; Blanchard, P.; Bosshard, P.; Chavan, R.; Coda, S.; Duval, B. P.; Fasel, D.; Favre, A. (2000-04-10). "Steady-State Fully Noninductive Current Driven by Electron Cyclotron Waves in a Magnetically Confined Plasma". Physical Review Letters. 84 (15): 3322–3325. Bibcode: 2000PhRvL..84.3322S. doi: 10.1103/PhysRevLett.84.3322. ISSN 0031-9007. PMID 11019080.
- ^ Karpushov, Alexander N.; Bagnato, Filippo; Baquero-Ruiz, Marcelo; Coda, Stefano; Colandrea, Claudia; Dolizy, Frédéric; Dubray, Jérémie; Duval, Basil P.; Fasel, Damien; Fasoli, Ambrogio; Jacquier, Rémy; Lavanchy, Pierre; Marlétaz, Blaise; Martin, Yves; Martinelli, Lorenzo (February 2023). "Upgrade of the neutral beam heating system on the TCV tokamak – second high energy neutral beam". Fusion Engineering and Design. 187: 113384. doi: 10.1016/j.fusengdes.2022.113384.
- ^ Reimerdes, H.; Duval, B.P.; Elaian, H.; Fasoli, A.; Février, O.; Theiler, C.; Bagnato, F.; Baquero-Ruiz, M.; Blanchard, P.; Brida, D.; Colandrea, C.; De Oliveira, H.; Galassi, D.; Gorno, S.; Henderson, S. (2021-02-01). "Initial TCV operation with a baffled divertor". Nuclear Fusion. 61 (2): 024002. Bibcode: 2021NucFu..61b4002R. doi: 10.1088/1741-4326/abd196. hdl: 21.11116/0000-0007-D639-8. ISSN 0029-5515. S2CID 234294126.
- ^ TCV Auxiliary Heating.
- ^ Keeping fusion research on the boil: Three tokamaks and one stellarator. August 2015
External links
-
TCV official site
- TCV Technical data as of Oct 2012
Fusion power, processes and devices | |||||||||||||||||||||||||||||||||||||||||||
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| Processes, methods |
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Devices, experiments |
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