Consequences of plasma rotation for neoclassical tearing mode suppression by electron cyclotron current drive

Ayten, B.; Westerhof, E.

doi:10.1063/1.4751873

Cited by 13 publications

(19 citation statements)

References 40 publications

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“…First of all, it should be determined whether the power required for complete NTM suppression remains within the capabilities of the system. Furthermore, it affects the decision as to whether modulation capabilities should be retained (which opens also the question of the detailed dynamical model of the ECCD process, as the island rotation frequency in the laboratory frame and the collision frequency on which ECCD establishes could be comparable [19,20]). Finally, the profile width also affects the steering accuracy required to compensate possible offsets of the deposition profile with respect to the island.…”

Section: Introductionmentioning

confidence: 99%

On recent results in the modelling of neoclassical-tearing-mode stabilization via electron cyclotron current drive and their impact on the design of the upper EC launcher for ITER

et al. 2015

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Electron cyclotron wave beams injected from a launcher placed in the upper part of the vessel will be used in ITER to control MHD instabilities, in particular neoclassical tearing modes (NTMs). Simplified NTM stabilization criteria have been used in the past to guide the optimization of the launcher. Their derivation is reviewed in this paper and their range of applicability clarified. Moreover, possible effects leading to a deterioration of the predicted performance are discussed. Particularly critical in this context is the broadening of the EC deposition profiles. It is argued that the most detrimental effect for ITER is likely to be the scattering of the EC beams from density fluctuations due to plasma turbulence, resulting in a beam broadening by about a factor of two. The combined impact of these effects with that of beam misalignment (with respect to the targeted surface) is investigated by solving the Rutherford equation in a form that retains the most relevant terms. The perspectives for NTM stabilization in the Q = 10 ITER scenario are discussed.

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Section: Introductionmentioning

confidence: 99%

On recent results in the modelling of neoclassical-tearing-mode stabilization via electron cyclotron current drive and their impact on the design of the upper EC launcher for ITER

et al. 2015

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“…The second case concerns the effect of density fluctuations of different orders of magnitude encountered along propagation. In ITER, the spatial range of such fluctuations is expected to vary within [1,20] cm [28]. With a calculation like above, one finds the range of values of κ in the vicinity of the fluctuation to be [5.6, 99.2].…”

Section: Limit Of Validity Of Asymptotic Methodsmentioning

confidence: 99%

“…Clearly for n = 0 and 1 one obtains the intermediate equations in zero and first order, from which (7) and (9) are derived (for more details see, e.g., [10,11]). The amplitude terms of higher-order may be calculated iteratively using (20), as it is already in the formΛ ·Ā n =Ω(Ā n−1 ), or by derivation and solution of a separate transport equation for each A n , in analogy to (9). This exact computation is beyond the scope of this article and will be treated in a future work.…”

Section: Limit Of Validity Of Asymptotic Methodsmentioning

confidence: 99%

“…In some cases, it may be important to address the actual tokamak equilibrium, also in the presence of MHD instabilities which result to the appearance of magnetic islands. Since ECRH/ECCD is used for the control/suppression of such phenomena, it may be also crucial to estimate the effect of the presence of islands on the power absorption and current drive [19,20]. A second issue is related to the description of the transformation of the initially assumed Gaussian wave beam to a more complicated wave object due to localization, asymmetry and inhomogeneity in the absorption.…”

Section: Introductionmentioning

confidence: 99%

“…As an example, we briefly refer to the case of EC propagation in the presence of magnetic islands (one may find extensive studies on this topic in [19,20]). The issue of relevance here is that, in most studies of ECCD-based NTM stabilization, the analysis of the propagation and deposition has been performed in terms of the unperturbed magnetic topology, taking into account only the flux surface of interest while ignoring any effects from the islands.…”

Section: The Problem Of Inaccuracy Introduced By Non-realistic Equilimentioning

confidence: 99%

See 2 more Smart Citations

On the Simplification of the Modeling of Electron-Cyclotron Wave Propagation in Thermonuclear Fusion Plasmas

Tsironis

2013

PIER B

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Abstract-The launching of high-frequency electromagnetic waves into fusion plasmas is an effective method for plasma heating and noninductive current drive. In addition, the reflection of electromagnetic waves on the plasma cutoffs is utilized in electron density diagnostic measurements. The scope of this article is to comment on the standard approximations made in the simulation of electron-cyclotron wave propagation and absorption in tokamak plasmas, in connection to the established modeling tools and the underlying physics, as well as to illustrate the limits of their validity, especially regarding the applicability to ITER-related studies and beyond. The identification of possible gaps in the current state-of-the-art and the implication of new requirements for theory and modeling are also discussed.

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Modelling effects of edge density fluctuations on electron-cyclotron current drive used for neoclassical tearing mode stabilization

et al. 2021

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In this work we study the undesired effects of electron density fluctuations (in the form of blob structures which may exist in the edge region of tokamak plasmas) to the electron-cyclotron wave propagation and current drive in connection to the efficiency of neoclassical tearing mode stabilization. Our model involves the evaluation of the driven current in the presence of density perturbations, by using a combination of a wave solver based on the transfer matrix and electromagnetic homogenization methods for the propagation part prior to and inside the region of these structures (where standard asymptotic propagation methods may not be valid due to the short-wavelength limit breakdown), with a ray tracing code including island geometry effects and current drive computation for the propagation past the perturbed region. The computed driven current is input into the modified Rutherford equation in order to estimate the consequences of the wave deformation (driven by the density fluctuations) to the mode stabilization.

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Consequences of plasma rotation for neoclassical tearing mode suppression by electron cyclotron current drive

Cited by 13 publications

References 40 publications

On recent results in the modelling of neoclassical-tearing-mode stabilization via electron cyclotron current drive and their impact on the design of the upper EC launcher for ITER

On recent results in the modelling of neoclassical-tearing-mode stabilization via electron cyclotron current drive and their impact on the design of the upper EC launcher for ITER

On the Simplification of the Modeling of Electron-Cyclotron Wave Propagation in Thermonuclear Fusion Plasmas

Modelling effects of edge density fluctuations on electron-cyclotron current drive used for neoclassical tearing mode stabilization

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