Shear reversal and MHD activity during pellet enhanced performance pulses in JET

Hugon, M.; Milligen, B. Ph. van; Smeulders, P.; Appel, L.C.; Bartlett, D.V.; Boucher, D.; Edwards, A. W.; Eriksson, L.‐G.; Gowers, C.; Hender, T. C.; Huysmans, G. T. A.; Jacquinot, J.; Kupschus, P.; Porte, L.; Rebut, P.H.; Start, D.F.H.; Tibone, F.; Tubbing, B.J.D.; Watkins, M.L.; Zwingmann, W.

doi:10.1088/0029-5515/32/1/i04

Cited by 199 publications

(116 citation statements)

References 14 publications

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“…4 for q = 3, s^ = -0. 5 Similar to what was found in the fluid theory for the PVS mode in cold plasmas, the stabilizing effects of the negative magnetic shear are strongest for lower q plasmas. For example, for q = 1.5, 7/w+, -0.4, at s^ = 0.5 while -0.2 for s^ = -0.5.…”

Section: A Magnetic Shear Variationsupporting

confidence: 68%

Study of microinstabilities in toroidal plasmas with negative magnetic shear

et al. 1996

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The micreinstabilities driven by a pardel velocity shear, and a temperature gradient of ions are studied in toroidal plasmas with negative magnetic shear. Both the fluid and the gyrekinetic formulations are investigated. It is found that for a broad range of parameters, the linear growth rates of the modes are lower, and the threshold temperature gradient q k is higher €or plasmas with negative magnetic shear compared to plasmas with p'ositive magnetic shear of equal magnitude. The reduction in the growth rate (with negative shear), although not insigdicant , does not seem to be enough to account for the dramatic improvement in the confinement observed experimentally. Other possible physical mechanisms for the improved confinement are discussed.

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Section: A Magnetic Shear Variationsupporting

confidence: 68%

Study of microinstabilities in toroidal plasmas with negative magnetic shear

et al. 1996

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“…A carefully MHD analysis of the JET PEP mode [124] -a representative of the peaked density profile confinement category -showed that also in this case the q-profile seems to be reversed. Specifically, the density gradient is very effective in flattening the qprofile.…”

Section: The Universal Role Of Shear Flow Decorrelation [47]mentioning

confidence: 89%

The history of research into improved confinement regimes

Wagner

2017

EPJ H

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Abstract. Increasing the pressure by additional heating of magnetically confined plasmas had the consequence that turbulent processes became more violent and plasma confinement degraded. Since this experience from the early 1980ies, fusion research was dominated by the search for confinement regimes with improved properties. It was a gratifying experience that toroidally confined plasmas are able to self-organise in such a way that turbulence diminishes, resulting in a confinement with good prospects to reach the objectives of fusion R&D. The understanding of improved confinement regimes revolutionized the understanding of turbulent transport in high-temperature plasmas. In this paper the story of research into improved confinement regimes will be narrated starting with 1980.

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“…The pellet enhanced performance ͑PEP͒ mode 16 was achieved in the Joint European Torus. 17 In the PEP mode, central deposition from pellet fueling and central heating in the ion cyclotron range of frequencies can lead to strongly peaked density profiles that produce the ITBs with the negative shear region in the plasma core.…”

Section: Introductionmentioning

confidence: 99%

Superdense core mode in the Large Helical Device with an internal diffusion barrier

et al. 2007

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In reduced recycling discharges using a local island divertor in the Large Helical Device ͓O. Motojima, H. Yamada, A. Komori et al., Phys. Plasmas 6, 1843 ͑1999͔͒, a stable high-density plasma develops in the core region when a series of pellets is injected. A core region with ϳ5 ϫ 10 20 m −3 and temperature of 0.85 keV is maintained by an internal diffusion barrier ͑IDB͒. The density gradient at the IDB ͑r / a ϳ 0.6͒ is very high, and the particle confinement time in the core region is ϳ0.4 s. Because of the increase in the central pressure, a large Shafranov shift up to ϳ0.3 m is observed. The critical ingredients for IDB formation are a strongly pumped divertor to reduce edge recycling, and multiple pellet injection to ensure efficient central fueling. No serious magnetohydrodynamics activity and impurity accumulation have been observed so far in this improved discharge.

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Shear reversal and MHD activity during pellet enhanced performance pulses in JET

Cited by 199 publications

References 14 publications

Study of microinstabilities in toroidal plasmas with negative magnetic shear

Study of microinstabilities in toroidal plasmas with negative magnetic shear

The history of research into improved confinement regimes

Superdense core mode in the Large Helical Device with an internal diffusion barrier

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