Analytic dispersion relation of energetic particle driven geodesic acoustic modes and simulations with NEMORB

Zarzoso, D.; Biancalani, A.; Bottino, A.; Lauber, P.; Poli, E.; Girardo, J. B.; Garbet, X.; Dümont, R.

doi:10.1088/0029-5515/54/10/103006

Cited by 36 publications

(101 citation statements)

References 20 publications

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“…Contrary to what was found in the q = 3 case, the threshold values found in the q = 2 case are similar whether FOW effects are taken into account (Ref. 21) or not (present model). This is consistent with Ref.…”

Section: Impact Of Flr/fow Effects On the Growth Ratesupporting

confidence: 65%

“…It is worth noting that the link between GAMs and EGAMs is thus different according to the value of the safety factor q: for q = 1.6, the EGAM originates from the GAM; while for q = 3, the GAM and the EGAM belong to different mode branches. The existence of two different kinds of EGAMs has also been shown numerically 21 with the gyrokinetic code NEMORB 22,23 .…”

Section: Resultsmentioning

confidence: 95%

“…The impacts of FLR/FOW effects on EGAMs, together with a detailed comparison of the analytic dispersion relation with gyrokinetic simulations, are analysed in Ref. 21.…”

Section: Discussionmentioning

confidence: 99%

“…As a matter of fact, simulations taking FOW effects into account made with the gyrokinetic code NEMORB, in the D-D case with parameters q = 2,ū = 2.8, τ k = 1 and T t /T e = 1, indicate 21 that the EGAM excitation threshold is reached at n k /n eq = 5%. With the present analytical model, we find for the same parameters a threshold of n k /n eq = 4%.…”

Section: Impact Of Flr/fow Effects On the Growth Ratementioning

confidence: 99%

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Relation between energetic and standard geodesic acoustic modes

et al. 2014

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Geodesic Acoustic Modes (GAMs) are electrostatic, axisymmetric modes which are non-linearly excited by turbulence. They can also be excited linearly by fast-particles; they are then called Energetic-particle-driven GAMs (EGAMs). Do GAMs and EGAMs belong to the same mode branch? Through a linear, analytical model, in which the fast particles are represented by a Maxwellian bump-on-tail distribution function, we find that the answer depends on several parameters. For low values of the safety factor q and for high values of the fast ion energy, the EGAM originates from the GAM. On the contrary, for high values of q and for low values of the fast ion energy, the GAM is not the mode which becomes unstable when fast particles are added: the EGAM then originates from a distinct mode, which is strongly damped in the absence of fast particles. The impact of other parameters is further explored: ratio of the ion temperature to the electron temperature, width of the fast particle distribution, mass and charge of the fast ions. The ratio between the EGAM and the GAM frequencies was found in experiments (DIII-D) and in non-linear numerical simulations (code GYSELA) to be close to 1/2: the present analytical study allows one to recover this ratio.

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Section: Impact Of Flr/fow Effects On the Growth Ratesupporting

confidence: 65%

Section: Resultsmentioning

confidence: 95%

“…The impacts of FLR/FOW effects on EGAMs, together with a detailed comparison of the analytic dispersion relation with gyrokinetic simulations, are analysed in Ref. 21.…”

Section: Discussionmentioning

confidence: 99%

Section: Impact Of Flr/fow Effects On the Growth Ratementioning

confidence: 99%

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Relation between energetic and standard geodesic acoustic modes

et al. 2014

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“…where n sp (ψ), T sp (ψ) are species density and temperature profiles along the radial coordinate ψ, which is the poloidal flux. A symmetric two-bumps-on-tail distribution function has been used in this work for the fast species 41,42 . This distribution assumes a flat temperature profile of the fast species:…”

Section: B Discretizationmentioning

confidence: 99%

Implementation of energy transfer technique in ORB5 to study collisionless wave-particle interactions in phase-space

Novikau

Biancalani

Bottino

et al. 2021

Computer Physics Communications

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A new diagnostic has been developed to investigate the wave-particle interaction in the phase-space in gyrokinetic particle-in-cell codes. Based on the projection of energy transfer terms onto the velocity space, the technique has been implemented and tested in the global code ORB5 and it gives an opportunity to localise velocity domains of maximum wave-plasma energy exchange for separate species. Moreover, contribution of different species and resonances can be estimated as well, by integrating the energy transfer terms in corresponding velocity domains. This Mode-Plasma-Resonance (MPR) diagnostic has been applied to study the dynamics of the Energetic-particle-induced Geodesic Acoustic Modes (EGAMs) in an ASDEX Upgrade shot, by analysing the influence of different species on the mode time evolution.Since the equations on which the diagnostic is based, are valid in both linear and nonlinear cases, this approach can be applied to study nonlinear plasma effects. As a possible future application, the technique can be used, for instance, to investigate the nonlinear EGAM frequency chirping, or the plasma heating due to the damping of the EGAMs.

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Saturation of energetic-particle-driven geodesic acoustic modes due to wave–particle nonlinearity

et al. 2017

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The nonlinear dynamics of energetic-particle (EP) driven geodesic acoustic modes (EGAM) is investigated here. A numerical analysis with the global gyrokinetic particle-in-cell code ORB5 is performed, and the results are interpreted with the analytical theory, in close comparison with the theory of the beam-plasma instability. Only axisymmetric modes are considered, with a nonlinear dynamics determined by wave-particle interaction. Quadratic scalings of the saturated electric field with respect to the linear growth rate are found for the case of interest. As a main result, the formula for the saturation level is provided. Near the saturation, we observe a transition from adiabatic to non-adiabatic dynamics, i.e. the frequency chirping rate becomes comparable to the resonant EP bounce frequency. The numerical analysis is performed here with electrostatic simulations with circular flux surfaces, and kinetic effects of the electrons are neglected.

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Analytic dispersion relation of energetic particle driven geodesic acoustic modes and simulations with NEMORB

Cited by 36 publications

References 20 publications

Relation between energetic and standard geodesic acoustic modes

Relation between energetic and standard geodesic acoustic modes

Implementation of energy transfer technique in ORB5 to study collisionless wave-particle interactions in phase-space

Saturation of energetic-particle-driven geodesic acoustic modes due to wave–particle nonlinearity

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