Model C stellarator

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Model C stellarator
Device type Stellarator
Location Princeton, New Jersey, United States
Affiliation Princeton Plasma Physics Laboratory
Technical specifications
Minor radius5–7.5 cm (2.0–3.0 in)
Magnetic field 3.5 T (35,000 G)
History
Date(s) of construction1961
Year(s) of operation1962–1969
Preceded byModel A/B stellarators [1]
Succeeded by Symmetric Tokamak (ST)

The Model C stellarator was the first large-scale stellarator to be built, during the early stages of fusion power research. Planned since 1952, construction began in 1961 at what is today the Princeton Plasma Physics Laboratory (PPPL). [1] The Model C followed the table-top sized Model A, and a series of Model B machines that refined the stellarator concept and provided the basis for the Model C, which intended to reach break-even conditions. Model C ultimately failed to reach this goal, producing electron temperatures of 400 eV when about 100,000 were needed. In 1969, after UK researchers confirmed that the USSR's T-3 tokamak was reaching 1000 eV, the Model C was converted to the Symmetrical Tokamak, and stellarator development at PPPL ended.

Contents

Design parameters

The Model C had a racetrack shape. The total circumference of the magnetic axis was 12 m [2] . The plasma could have a 5-7.5 cm minor radius. Magnetic coils could produce a toroidal field (along the tube) of 35,000 Gauss. [1] It was only capable of pulsed operation.

It had a divertor in one of the straight sections. In the other it could inject 4 MW of 25 MHz ion cyclotron resonance heating (ICRH).

It had helical windings on the curved sections.

Results

An average ion temperature of 400 eV was reached in 1969.

History

Construction funding/approval was announced in April 1957 with the design based on Katherine Weimer's efforts in fundamental research. [3] [4]

It started operating March 1962. [5]

The Model C was reconfigured as a tokamak in 1969, [1] becoming the Symmetric Tokamak (ST). [6]

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References

  1. 1 2 3 4 Stix, T. H. (1998). "Highlights in early stellarator research at Princeton" (PDF). J. Plasma Fusion Res. 1: 3–8.
  2. Yoshikawa, S.; Stix, T.H. (1985-09-01). "Experiments on the Model C stellarator". Nuclear Fusion. 25 (9): 1275–1279. doi:10.1088/0029-5515/25/9/047. ISSN   0029-5515.
  3. Princeton Alumni Weekly, Volume 57. April 19. p9
  4. Johnson, John L.; Greene, John M. (September 2000). "Katherine Ella Mounce Weimer". Physics Today. 53 (9): 88. doi: 10.1063/1.1325250 . ISSN   0031-9228.
  5. See 1962
  6. See 1969,1970

Further reading