Experimental Demonstration of Improved Neoclassical Transport with Quasihelical Symmetry

Canik, J.; Anderson, David T.; Anderson, F. S. B.; Likin, K. M.; Talmadge, J. N.; Zhai, K.

doi:10.1103/physrevlett.98.085002

Cited by 87 publications

(81 citation statements)

References 21 publications

(19 reference statements)

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“…The visible departure from quasi-helical symmetry is instead largely due to the coil ripple produced by the twelve modular coils in each field period. In experiments, the improvement in confinement for thermal and fast particles predicted for quasi-helical symmetry has been demonstrated in HSX by also considering discharges in which the magnetic configuration has been altered to purposely spoil the quasi-symmetry [62,63].…”

Section: Configurationsmentioning

confidence: 99%

Benchmarking of the mono-energetic transport coefficients—results from the International Collaboration on Neoclassical Transport in Stellarators (ICNTS)

et al. 2011

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Numerical results for the three mono-energetic transport coefficients required for a complete neoclassical description of stellarator plasmas have been benchmarked within an international collaboration. These transport coefficients are flux-surface-averaged moments of solutions to the linearised drift kinetic equation which have been determined using field-line-integration techniques, Monte Carlo simulations, a variational method employing Fourier-Legendre test functions and a finite difference scheme. The benchmarking has been successfully carried out for past, present and future devices which represent different optimisation strategies within the extensive configuration space available to stellarators.A qualitative comparison of the results with theoretical expectations for simple model fields is provided. The behaviour of the results for the mono-energetic radial and parallel transport coefficients can be largely understood from such theoretical considerations but the mono-energetic bootstrap current coefficient exhibits characteristics which have not been predicted.

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Section: Configurationsmentioning

confidence: 99%

Benchmarking of the mono-energetic transport coefficients—results from the International Collaboration on Neoclassical Transport in Stellarators (ICNTS)

et al. 2011

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“…In practice it is not possible to create a perfectly quasisymmetric magnetic field, but it is possible to come close. Currently the most quasisymmetric stellarator is the HSX experiment [11], where the "effective helical ripple" is less than 1% over most of the plasma volume.…”

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confidence: 99%

Intrinsic Ambipolarity and Rotation in Stellarators

2008

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It is demonstrated that collisional plasma transport is intrinsically ambipolar only in magnetic configurations that are quasiaxisymmetric or quasihelically symmetric. Only in such configurations can the plasma rotate freely, and then only in the direction of quasisymmetry. In a nonquasisymmetric magnetic field, it is shown that the average radial electric field is determined by parallel viscosity, which in turn is usually governed by collisional processes. Locally, the radial electric field may be affected by turbulent Reynolds stress producing zonal flows, but on a radial average, taken on a length scale exceeding the ion gyroradius, it is determined by parallel viscosity, at least if the turbulence is electrostatic and obeys the conventional gyrokinetic orderings. This is different from the situation in a tokamak or a quasisymmetric stellarator, where there is no flow damping by parallel viscosity in the symmetry direction and the turbulent Reynolds stress may affect the global radial electric field.

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“…Consequently, basic reactor properties such as good magnetic surfaces, favourable equilibrium properties and magnetohydrodynamic stability at sufficiently high normalized plasma pressure, β, and satisfactory thermal and fast particle confinement should be achievable. Besides Wendelstein 7-AS, which was partially optimized with respect to reduced equilibrium currents [3], recent experimental results confirm the effectiveness of quasisymmetry regarding improved neoclassical confinement [4].…”

Section: Introductionmentioning

confidence: 98%

A stellarator reactor based on the optimization criteria of Wendelstein 7-X

Wolf

Team

2008

Fusion Engineering and Design

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Wendelstein 7-X is an optimized stellarator including a divertor concept for energy and particle exhaust. The main properties of Wendelstein 7-X are discussed in the context of the application to a stellarator fusion reactor -the Helical Advanced Stellarator concept which is based on the same optimization criteria as Wendelstein 7-X. Experience gained from the design, construction of components and the starting assembly of Wendelstein 7-X is presented.

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Experimental Demonstration of Improved Neoclassical Transport with Quasihelical Symmetry

Cited by 87 publications

References 21 publications

Benchmarking of the mono-energetic transport coefficients—results from the International Collaboration on Neoclassical Transport in Stellarators (ICNTS)

Benchmarking of the mono-energetic transport coefficients—results from the International Collaboration on Neoclassical Transport in Stellarators (ICNTS)

Intrinsic Ambipolarity and Rotation in Stellarators

A stellarator reactor based on the optimization criteria of Wendelstein 7-X

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