Nonlinear velocity redistribution caused by energetic-particle-driven geodesic acoustic modes, mapped with the beam-plasma system

Biancalani, A.; Carlevaro, Nakia; Bottino, A.; Montani, Giovanni; Qiu, Zhiyong

doi:10.1017/s002237781800123x

Cited by 9 publications

(15 citation statements)

References 44 publications

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“…In the following, with the aim of illustrating the direct implementation of the BPS as a paradigm for describing the burning plasma scenario, we introduce a mapping technique between the reduced radial profile of real systems and the velocity coordinate of the BPS. A validation of this approach can be found in Carlevaro et al (2019) (see also Carlevaro et al 2016b), where the ITER 15 MA baseline scenario is addressed in the presence of the least damped 27 toroidal AEs, and also in Biancalani et al (2018) for an application to the case of EP-driven geodesic acoustic modes.…”

Section: Hamiltonian Description Of the Beam-plasma Interactionmentioning

confidence: 99%

“…Without entering the details of this step, η can be evaluated by assuming a direct proportionality between the linear growth rates (normalized to the mode frequency) of the BPS and the AE/EP scenario. The proportionality constant can be fixed requiring that the nonlinear transport is preserved (Biancalani et al 2018;Carlevaro et al 2019). Then, the integration of the linear dispersion relation for the BPS, which is analysed in the next section, directly provides the value of the density parameter.…”

Section: Hamiltonian Description Of the Beam-plasma Interactionmentioning

confidence: 99%

“…2016 b ), where the ITER 15 MA baseline scenario is addressed in the presence of the least damped 27 toroidal AEs, and also in Biancalani et al. (2018) for an application to the case of EP-driven geodesic acoustic modes.…”

Section: Hamiltonian Description Of the Beam–plasma Interactionmentioning

confidence: 99%

“…The proportionality constant can be fixed requiring that the nonlinear transport is preserved (Biancalani et al. 2018; Carlevaro et al. 2019).…”

Section: Hamiltonian Description Of the Beam–plasma Interactionmentioning

confidence: 99%

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Contributions to the linear and nonlinear theory of the beam–plasma interaction

et al. 2020

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We focus our attention on some relevant aspects of the beam–plasma instability in order to refine some features of the linear and nonlinear dynamics. After a re-analysis of the Poisson equation and of the assumption dealing with the background plasma in the form of a linear dielectric, we study the non-perturbative properties of the linear dispersion relation, showing the necessity for a better characterization of the mode growth rate in those flat regions of the distribution function where the Landau formula is no longer predictive. We then upgrade the original $N$ -body approach in O'Neil et al. (Phys. Fluids, vol. 14, 1971, pp. 1204–1212), in order to include a return current in the background plasma. This correction term is responsible for smaller saturation levels and growth rates of the Langmuir modes, as result of the energy density transferred to the plasma via the return current. Finally, we include friction effects, as those due to the collective influence of all the plasma charges on the motion of the beam particles. The resulting force induces a progressive resonance detuning, because particles are losing energy and decreasing their velocity. This friction phenomenon gives rise to a deformation of the distribution function, associated with a significant growth of the less energetic particle population. The merit of this work is to show how a fine analysis of the beam–plasma instability outlines a number of subtleties about the linear, intermediate and late dynamics which can be of relevance when such a system is addressed as a paradigm to describe relevant nonlinear wave–particle phenomena (Chen & Zonca, Rev. Mod. Phys., vol. 88, 2016, 015008).

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Section: Hamiltonian Description Of the Beam-plasma Interactionmentioning

confidence: 99%

Section: Hamiltonian Description Of the Beam-plasma Interactionmentioning

confidence: 99%

Section: Hamiltonian Description Of the Beam–plasma Interactionmentioning

confidence: 99%

“…The proportionality constant can be fixed requiring that the nonlinear transport is preserved (Biancalani et al. 2018; Carlevaro et al. 2019).…”

Section: Hamiltonian Description Of the Beam–plasma Interactionmentioning

confidence: 99%

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Contributions to the linear and nonlinear theory of the beam–plasma interaction

et al. 2020

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“…Whereas, positive gradients of the distribution functions in velocity space are needed to drive EGAMs, and as a consequence of which a certain portion of EPs will be redistributed to lower energies. [26]. In previous work, analytical anisotropic distribution functions are bump-on-tail [9,26,8] and slowing down with pitch dependency [6,11,20,8], as well as single pitch Maxwellian [8].…”

Section: Introductionmentioning

confidence: 99%

Gyrokinetic modelling of anisotropic energetic particle driven instabilities in tokamak plasmas

Rettino,

Hayward-Schneider,

Biancalani

et al. 2022

Preprint

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Energetic particles produced by neutral beams are observed to excite energetic-particle-driven geodesic acoustic modes (EGAMs) in tokamaks. We study the effects of anisotropy of distribution function of the energetic particles on the excitation of such instabilities with ORB5, a gyrokinetic particle-in-cell code. Numerical results are shown for linear electrostatic simulations with ORB5. The growth rate is found to be sensitively dependent on the phase-space shape of the distribution function. The behavior of the instability is qualitatively compared to the theoretical analysis of dispersion relations. Realistic neutral beam energetic particle anisotropic distributions are obtained from the heating solver RABBIT and are introduced into ORB5 as input distribution function. Results show a dependence of the growth rate on the injection angle. A qualitative comparison to experimental measurements is presented and few disagreements between them are found, being the growth rate in the simulations much lower than that from experiments. An explanation for the difference is advanced.

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Nonlinear dynamics of energetic-particle driven geodesic acoustic modes in ASDEX Upgrade

et al. 2020

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Turbulence in tokamaks generates radially sheared zonal flows (ZFs). Their oscillatory counterparts, geodesic acoustic modes (GAMs), appear due to the action of the magnetic field curvature. The GAMs can also be driven unstable by an anisotropic energetic particle (EP) population leading to the formation of global radial structures, called EGAMs. The EGAMs might play the role of an intermediate agent between the EPs and thermal plasma, by redistributing EP energy to the bulk plasma through collisionless wave-particle interaction. In such a way, the EGAMs might contribute to the plasma heating. Thus, investigation of EGAM properties, especially in the velocity space, is necessary for precise understanding of the transport phenomena in tokamak plasmas. In this work, the nonlinear dynamics of EGAMs is investigated with the help of a Mode-Particle-Resonance (MPR) diagnostic recently implemented in the global gyrokinetic (GK) particle-in-cell code ORB5. This enables to investigate the relative importance and the evolution of the resonances responsible for the ion and electron Landau damping, and of the EP drive. An ASDEX Upgrade discharge is chosen as a reference case for this investigation due to its rich EP nonlinear dynamics.

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Nonlinear velocity redistribution caused by energetic-particle-driven geodesic acoustic modes, mapped with the beam-plasma system

Cited by 9 publications

References 44 publications

Contributions to the linear and nonlinear theory of the beam–plasma interaction

Contributions to the linear and nonlinear theory of the beam–plasma interaction

Gyrokinetic modelling of anisotropic energetic particle driven instabilities in tokamak plasmas

Nonlinear dynamics of energetic-particle driven geodesic acoustic modes in ASDEX Upgrade

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