Electromagnetic turbulence suppression by energetic particle driven modes

Siena, A. Di; Görler, T.; Poli, E.; Navarro, A. Bañón; Biancalani, A.; Jenko, F.

doi:10.1088/1741-4326/ab4088

Cited by 71 publications

(117 citation statements)

References 43 publications

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“…Attempted non-linear simulations did not reach a convincingly long steady saturated state and this hypothesis is not excluded. Furthermore, it seems that this investigation and the assessment of the results should probably also include both the role of nonlinearly excited energetic particle driven modes [35] and an values, which is a general issue, see e.g. [32,31].…”

Section: Results From Gyrokinetic Calculationsmentioning

confidence: 99%

Heat transport driven by the ion temperature gradient and electron temperature gradient instabilities in ASDEX Upgrade H-modes

et al. 2019

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A study of the properties of the turbulence-driven ion and electron heat fluxes, is presented. Dedicated H-mode experiments taking advantage of the on-axis and off-axis possibilities of both neutral beam injection and electron cyclotron resonance heating available on the ASDEX Upgrade tokamak were carried out. The experimental results are interpreted by comparisons with gyrokinetic calculations. Ion heat transport is, as expected, driven by the Ion Temperature Gradient (ITG) instability with the features predicted by theory: increase of the driven heat flux above a threshold in normalised gradient. In addition the main effects known to impact on the stability of the turbulence, temperature ratio and fast ions population, are exhibited by the experimental results and agree with the gyrokinetic calculations. It is known that the ITG also contributes to the electron heat flux, but that an electron instability can be required in addition when the ITG contribution does not drive the whole imposed electron heating. This situation, investigated by adding electron cyclotron heating, indicates that in the experiments presented here the Electron Temperature Gradient instability develops.

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Section: Results From Gyrokinetic Calculationsmentioning

confidence: 99%

Heat transport driven by the ion temperature gradient and electron temperature gradient instabilities in ASDEX Upgrade H-modes

et al. 2019

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“…Plasma quasineutrality is always fulfilled. Moreover, we consider a=L Tf ¼ 18, which is consistent with the realistic values observed in ICRF H-minority heating in tokamak experiments [11,20]. The hydrogen minority is modeled with an equivalent Maxwellian background.…”

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confidence: 79%

Turbulence Suppression by Energetic Particle Effects in Modern Optimized Stellarators

2020

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Turbulent transport is known to limit the plasma confinement of present-day optimized stellarators. To address this issue, a novel method to strongly suppress turbulence in such devices is proposed, namely the resonant wave-particle interaction of suprathermal particles-e.g., from ion-cyclotron-resonancefrequency heating-with turbulence-driving microinstabilities like ion-temperature-gradient modes. The effectiveness of this mechanism is demonstrated via large-scale gyrokinetic simulations, revealing an overall turbulence reduction by up to 65% in the case under consideration. Comparisons with a tokamak configuration highlight the critical role played by the magnetic geometry and the first steps into the optimization of fast particle effects in stellarator devices are discussed. These results hold the promise of new and still unexplored stellarator scenarios with reduced turbulent transport, essential for achieving burning plasmas in future devices.

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“…The physics mechanisms behind the stabilization have been investigated in detail with GENE for the JET case. Part of the stabilization is due to an ES resonant linear effect associated to the ICRH fast ions [66], and part is due to a nonlinear EM effect caused by non-linear coupling of ITG, marginally stable Toroidal Alfven Eigenmodes and Zonal Flows [67]. This second mechanism is analogous to the non-linear EM stabilization of ITGs by the thermal plasma β (i.e.…”

Section: Recent Progress In Understanding and New Challenges For Imprmentioning

confidence: 99%

Progress and challenges in understanding core transport in tokamaks in support to ITER operations

Mantica

Angioni

Bonanomi

et al. 2019

Plasma Phys. Control. Fusion

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Fusion performance in tokamaks depends on the core and edge regions as well as on their nonlinear feedbacks. The achievable degree of edge confinement under the constraints of power handling in presence of a metallic wall is still an open question. Therefore, any improvement in the core temperature and density peaking is crucial for achieving target performance. This has motivated further progress in understanding core turbulent transport mechanisms, to help scenario development in present devices and improve predictive tools for ITER operations. In the last two decades, detailed experiments and their interpretation via the gyrokinetic theory of turbulent transport have led to a satisfactory level of understanding of the heat, particle, and momentum transport channels and of their mutual interactions. This paper presents some highlights of the progress, which stems from joint work of several devices and theory groups, in Europe and worldwide within the ITPA (International Tokamak Physics Activities) framework. On the other hand, the achievement of predictive capabilities of plasma profiles via integrated modeling, which also accounts for the nonlinear interactions inherent to the multi-channel nature of transport, is a priority in view of ITER. This requires using faster, reduced models, and the extent to which they capture the complex physics described by nonlinear gyrokinetics must be carefully evaluated. Present quasi-linear models match well experiments in baseline scenarios, and thus offer reliable predictions for the ITER reference scenario, but have issues in advanced scenarios. Some of these challenges are examined and discussed. In the longer term, advances in high performance computing will continue to drive physics discovery through increasingly complex gyrokinetic simulations, allowing also further development of reduced models. The development of neural network surrogate models is another recent advance that bridges the gap towards physics-based fast models for optimisation and control applications.

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Electromagnetic turbulence suppression by energetic particle driven modes

Cited by 71 publications

References 43 publications

Heat transport driven by the ion temperature gradient and electron temperature gradient instabilities in ASDEX Upgrade H-modes

Heat transport driven by the ion temperature gradient and electron temperature gradient instabilities in ASDEX Upgrade H-modes

Turbulence Suppression by Energetic Particle Effects in Modern Optimized Stellarators

Progress and challenges in understanding core transport in tokamaks in support to ITER operations

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