Advances in numerical simulations of ion cyclotron heating of non-Maxwellian plasmas

Brambilla, M.; Bilato, R.

doi:10.1088/0029-5515/49/8/085004

Cited by 53 publications

(124 citation statements)

References 29 publications

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“…The first two terms are respectively the linearized collision operator and the RF quasilinear operator, and S i ∆T is the source term required to maintain in steady-state charged species at different temperatures. All these terms are discussed in [2]. Here, new are the particle source S i nbi , representing NBI, and the particle loss term L i nbi , necessary to compensate the corresponding particle input.…”

Section: -Nbi Source In Ssfpqlmentioning

confidence: 99%

“…In the presence of ICRF heating the number of LPs necessary to obtain a convergent solution increases greatly when the distortion of the distribution functions from Maxwellians are relatively large for nearly parallel velocities, µ ∼ ±1. This follows from the convergence property of the series used to separate the µ and v dependence in the argument of the Bessel functions in the QLO [2]. A special effort, therefore, had to be devoted to reduce the round-off errors which limit the number of LPs which can be included in the numerical solution.…”

Section: -Nbi Source In Ssfpqlmentioning

confidence: 99%

“…As already noted in [2], the main limitation of the SSFPQL model is the absence of a term describing losses of very energetic ions. The first comparisons of the numerical and experimental neutron rates in the presence of simultaneous NBI and harmonic IC heating have further evidentiated the need of such a term.…”

Section: -Nbi Source In Ssfpqlmentioning

confidence: 99%

“…Numerical simulations of IC heating, therefore, require a self-consistency loop between a wave solver and a solver of the kinetic Fokker-Planck (FP) equation. In view of this, the full wave code TORIC has been recently modified to evaluate the coefficients of the wave equations with the ion distribution functions (DFs) calculated by FP solver SSFPQL, which, in turn, takes into account the quasilinear power source due to the radio-frequency (RF) waves [2]. At IC harmonics (ω = n Ω ci with n ≥ 2) ion heating is a finite Larmor radius (FLR) effect, and, therefore, preferentially accelerates ions with large Larmor radius, ρ k ⊥ > ∼ 1 with k ⊥ the perpendicular wave number, and ρ = v ⊥ /Ω ci .…”

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confidence: 99%

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Simulations of NBI-ICRF synergy with the full-wave TORIC package

Bilato

Brambilla

Horton³

et al. 2009

AIP Conference Proceedings

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Abstract. During the combined plasma heating with neutral beam injection (NBI) and waves in the ion cyclotron (IC) range of frequencies, the NBI fast ions are preferentially accelerated by IC waves close to the IC harmonics, as a consequence of finite Larmor radius (FLR) effects. Since the NBI fast ions are expected to have a strong influence on the wave absorption and propagation, we have implemented a NBI source in the quasilinear Fokker-Planck SSFPQL code, interfaced with the toroidal full-wave TORIC solver. In this implementation the NBI ionization sources are obtained from the output of a Monte Carlo code, such as FAFNER. The numerical scheme adopted in the TORIC-SSFPQL package allows to describe very anisotropic sources, such as NBI, and to iterate the solution of Maxwell's equation taking into account selfconsistently the fast ion tails. As a first application, we present modeling of an ASDEX-Upgrade discharge with combined NBI and ICRF heating. Keywords -Introduction. Neutral beam injection (NBI) and damping of fast waves (FW) inthe ion cyclotron (IC) range of frequencies are the standard methods of ion heating in magnetically confined plasmas. The combination of NBI and IC heating can produce high-energy ion tails. In present day devices, this can be used to address the physics of fast ions [1]. There is a close interplay between the formation of fast-ion tails and the propagation and absorption of IC waves. Numerical simulations of IC heating, therefore, require a self-consistency loop between a wave solver and a solver of the kinetic Fokker-Planck (FP) equation. In view of this, the full wave code TORIC has been recently modified to evaluate the coefficients of the wave equations with the ion distribution functions (DFs) calculated by FP solver SSFPQL, which, in turn, takes into account the quasilinear power source due to the radio-frequency (RF) waves [2]. At IC harmonics (ω = n Ω ci with n ≥ 2) ion heating is a finite Larmor radius (FLR) effect, and, therefore, preferentially accelerates ions with large Larmor radius, ρ k ⊥ > ∼ 1 with k ⊥ the perpendicular wave number, and ρ = v ⊥ /Ω ci . When NBI and harmonic IC heating are simultaneously present, therefore, rather strong synergetic effects can be expected. To simulate this situation, we have now extended SSFPQL to include the NBI source in the FP equation, as we briefly describe in the next section. In the last section we present the results of a first application to an ASDEX-Upgrade (AUG) discharge. -NBI source in SSFPQL.With simultaneous NBI and RF heating the steady-state quasilinear kinetic equation for ion species i is

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Section: -Nbi Source In Ssfpqlmentioning

confidence: 99%

Section: -Nbi Source In Ssfpqlmentioning

confidence: 99%

Section: -Nbi Source In Ssfpqlmentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Simulations of NBI-ICRF synergy with the full-wave TORIC package

Bilato

Brambilla

Horton³

et al. 2009

AIP Conference Proceedings

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“…The package TORIC-SSFPQL [1] for numerical simulations of Ion Cyclotron (IC) Heating in Tokamaks is particularly fast. This is due in part to the fact that in SSFPQL the solution of the surface-averaged quasilinear kinetic equation is obtained as a velocity dependent superposition of Legendre polynomials in the velocity pitch-angle.…”

Section: Introductionmentioning

confidence: 99%

Toroidal trapping effects in the surface-averaged Fokker-Planck SSFPQL solver

Bilato

Brambilla

2014

AIP Conference Proceedings

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Abstract. The kinetic equation solved by SSFPQL was obtained by surface-averaging the Fokker-Planck (FP) equation, thus neglecting both the finite width of the ion orbits and the poloidal modulation of their velocity. Owing to the latter effect and depending on the position of the resonance layer, a fraction of trapped particles do not even reach the ion-cyclotron resonance. In addition, since the resonant ions gain perpendicular energy, they tend to accumulate on trapped orbits barely intercepting the resonance. Still neglecting the effects due to the finite width of the orbits, here we discuss the form of the FP equation when the velocity modulation is taken into account. In particular, we examine the implementation of this effect in the quasilinear operator of SSFPQL, and present a few numerical results.

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LEOPARD: A grid‐based dispersion relation solver for arbitrary gyrotropic distributions

Astfalk

Jenko

2017

JGR Space Physics

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Particle velocity distributions measured in collisionless space plasmas often show strong deviations from idealized model distributions. Despite this observational evidence, linear wave analysis in space plasma environments such as the solar wind or Earth's magnetosphere is still mainly carried out using dispersion relation solvers based on Maxwellians or other parametric models. To enable a more realistic analysis, we present the new grid‐based kinetic dispersion relation solver LEOPARD (Linear Electromagnetic Oscillations in Plasmas with Arbitrary Rotationally‐symmetric Distributions) which no longer requires prescribed model distributions but allows for arbitrary gyrotropic distribution functions. In this work, we discuss the underlying numerical scheme of the code and we show a few exemplary benchmarks. Furthermore, we demonstrate a first application of LEOPARD to ion distribution data obtained from hybrid simulations. In particular, we show that in the saturation stage of the parallel fire hose instability, the deformation of the initial bi‐Maxwellian distribution invalidates the use of standard dispersion relation solvers. A linear solver based on bi‐Maxwellians predicts further growth even after saturation, while LEOPARD correctly indicates vanishing growth rates. We also discuss how this complies with former studies on the validity of quasilinear theory for the resonant fire hose. In the end, we briefly comment on the role of LEOPARD in directly analyzing spacecraft data, and we refer to an upcoming paper which demonstrates a first application of that kind.

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Advances in numerical simulations of ion cyclotron heating of non-Maxwellian plasmas

Cited by 53 publications

References 29 publications

Simulations of NBI-ICRF synergy with the full-wave TORIC package

Simulations of NBI-ICRF synergy with the full-wave TORIC package

Toroidal trapping effects in the surface-averaged Fokker-Planck SSFPQL solver

LEOPARD: A grid‐based dispersion relation solver for arbitrary gyrotropic distributions

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