Gyrokinetic simulations of plasma turbulence in a Z-pinch using a moment-based approach and advanced collision operators

Hoffmann, Annick; Frei, B. J.; Ricci, Paolo

doi:10.1017/s0022377823000284

Cited by 3 publications

(10 citation statements)

References 63 publications

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“…Second, we recall that the Laguerre polynomials are involved in the Bessel-Laguerre decomposition of (2.21), which converges non-monotonically with respect to the maximal Laguerre degree, explaining the non-monotonic convergence at the highest Laguerre modes in figure 3. We note that the convergence of the nonlinear GM simulations is set by the convergence of the peak linear growth rate of the ITG mode, which is in agreement with the findings of our previous work (Hoffmann et al 2023). In fact, the overestimate of the linear growth rates observed for the (4, 2) basis (see figure 1a) corresponds to an increased saturated transport value (see figure 2b) and a high amplitude of the GM spectrum on figure 3.…”

Section: Nonlinear Cyclone Base Casesupporting

confidence: 90%

“…Similarly to our previous work on the entropy mode (Hoffmann et al 2023), we observe a non-monotonic convergence of the GM growth rates with P and J. The GM approach converges to the correct growth rate with a smaller number of polynomials in the long-wavelength limit, k y ρ s 1, than at short wavelengths.…”

Section: Linear Convergence and Ion Temperature Gradient Stability Th...supporting

confidence: 80%

“…The convergence behaviour exhibits typical characteristics of spectral methods, that is an exponential and non-monotonic trend with P and J. It is worth noting that figure 1(b) reveals optimal convergence properties when P ∼ 2J, which justifies this choice also in previous works (Mandell et al 2022;Frei et al 2023;Hoffmann et al 2023). This is possibly related to the fact that H n is a Hermite polynomial of degree n in the parallel velocity coordinate, whereas L n is a Laguerre polynomial of degree 2n in the perpendicular velocity coordinate.…”

Section: Linear Convergence and Ion Temperature Gradient Stability Th...supporting

confidence: 71%

“…N pj = 0 for p > P or j > J. The truncation closure is the most straightforward to apply and shows good results in Frei et al (2022), Frei et al (2023) and Hoffmann et al (2023). We must note that, in collisionless simulations, the Hermite parallel coupling in (2.24), combined with the closure by truncation, may lead to recurrence effects, which yields a non-physical energy transfer from the highest to the lowest Hermite modes.…”

Section: Velocity Space Discretization and Closurementioning

confidence: 98%

“…The details of these operators and their projection onto the Hermite-Laguerre basis can be found in Frei et al (2021). For an overview of the qualitative differences between the aforementioned collision operators we also refer to Hoffmann et al (2023). We set the intensity of the collisions through the non-dimensional parameter ν, normalized by the ion-ion collision frequency…”

Section: Nonlinear Hermite-laguerre-fourier Pseudospectral Formulationmentioning

confidence: 99%

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Gyrokinetic moment-based simulations of the Dimits shift

Hoffmann,

Frei,

Ricci

2023

J. Plasma Phys.

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We present a convergence study of the gyromoment (GM) approach, which is based on projecting the gyrokinetic distribution function onto a Hermite–Laguerre polynomial basis, focused on the cyclone base case (CBC) (Lin et al., Phys. Rev. Lett., vol. 83, no. 18, 1999, pp. 3645–3648) and Dimits shift (Dimits et al., Phys. Plasmas, vol. 7, no. 3, 2000, pp. 969–983) as benchmarks. We report that the GM approach converges more rapidly in capturing the nonlinear dynamics of the CBC than the continuum GENE code (Jenko et al., Phys. Plasmas, vol. 7, no. 5, 2000, pp. 1904–1910) when comparing the number of points representing the velocity space. Increasing the velocity dissipation improves the convergence properties of the GM approach, albeit yielding a slightly larger saturated heat flux. By varying the temperature equilibrium gradient, we show that the GM approach successfully reproduces the Dimits shift (Dimits et al., Phys. Plasmas, vol. 7, no. 3, 2000, pp. 969–983) and effectively captures its width, which is in contrast to the gyrofluid framework. In the collisional regime, the convergence properties of the GM approach improve and a good agreement with previous global particle-in-cell results on transport is obtained (Lin et al., Phys. Rev. Lett., vol. 83, no. 18, 1999, pp. 3645–3648). Finally, we report that the choice of collision model has a minimal impact both on the ion temperature gradient growth rate and on the nonlinear saturated heat flux, at tokamak-relevant collisionality.

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Section: Nonlinear Cyclone Base Casesupporting

confidence: 90%

Section: Linear Convergence and Ion Temperature Gradient Stability Th...supporting

confidence: 80%

Section: Linear Convergence and Ion Temperature Gradient Stability Th...supporting

confidence: 71%

Section: Velocity Space Discretization and Closurementioning

confidence: 98%

Section: Nonlinear Hermite-laguerre-fourier Pseudospectral Formulationmentioning

confidence: 99%

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Gyrokinetic moment-based simulations of the Dimits shift

Hoffmann,

Frei,

Ricci

2023

J. Plasma Phys.

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Moment-based approach to the flux-tube linear gyrokinetic model

Frei,

Hoffmann,

Ricci

et al. 2023

J. Plasma Phys.

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This work reports on the development and numerical implementation of the linear electromagnetic gyrokinetic (GK) model in a tokamak flux-tube geometry using a moment approach based on the expansion of the perturbed distribution function on a velocity-space Hermite–Laguerre polynomials basis. A hierarchy of equations of the expansion coefficients, referred to as the gyro-moments (GMs), is derived. We verify the numerical implementation of the GM hierarchy in the collisionless limit by performing a comparison with the continuum GK code GENE, recovering the linear properties of the ion temperature gradient, trapped electron, kinetic ballooning and microtearing modes, as well as the collisionless damping of zonal flows. An analysis of the distribution functions and ballooning eigenmode structures is performed. The present investigation reveals the ability of the GM approach to describe fine velocity-space-scale structures appearing near the trapped and passing boundary and kinetic effects associated with parallel and perpendicular particle drifts. In addition, the effects of collisions are studied using advanced collision operators, including the GK Coulomb collision operator. The main findings are that the number of GMs necessary for convergence decreases with plasma collisionality and is lower for pressure gradient-driven modes, such as in H-mode pedestal regions, compared with instabilities driven by trapped particles and magnetic gradient drifts often found in the core. The accuracy of approximations often used to model collisions (relative to the GK Coulomb operator) is studied in the case of trapped electron modes, showing differences between collision operator models that increase with collisionality and electron temperature gradient, consistent with the results of Pan et al. (Phys. Rev. E, vol. 103, 2021, L051202). Such differences are not observed in other edge microinstabilities, such as microtearing modes. The importance of a proper collision operator model is also confirmed by analysing the collisional damping of geodesic acoustic modes and zonal flows.

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Full-F turbulent simulation in a linear plasma device using a gyro-moment approach

Frei,

Mencke,

Ricci

2024

Physics of Plasmas

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Simulations of plasma turbulence in a linear plasma device configuration are presented. These simulations are based on a simplified version of the gyrokinetic (GK) model proposed by Frei et al. [J. Plasma Phys. 86, 905860205 (2020)], where the full-F distribution function is expanded on a velocity-space polynomial basis allowing us to reduce its evolution to the solution of an arbitrary number of fluid-like equations for the expansion coefficients, denoted as the gyro-moments (GM). By focusing on the electrostatic and neglecting finite Larmor radius effects, a full-F GM hierarchy equation is derived to evolve the ion dynamics, which includes a nonlinear Dougherty collision operator, localized sources, and Bohm sheath boundary conditions. An electron fluid Braginskii model is used to evolve the electron dynamics, coupled to the full-F ion GM hierarchy equation via a vorticity equation where the Boussinesq approximation is used. A set of full-F turbulent simulations are then performed using the parameters of the LArge Plasma Device (LAPD) experiments with different numbers of ion GMs and different values of collisionality. The ion distribution function is analyzed illustrating the convergence properties of the GM approach. In particular, we show that higher-order GMs are damped by collisions in the high-collisional regime relevant to LAPD experiments. The GM results are then compared with those from two-fluid Braginskii simulations, finding qualitative agreement in the time-averaged profiles and statistical turbulent properties.

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Gyrokinetic simulations of plasma turbulence in a Z-pinch using a moment-based approach and advanced collision operators

Cited by 3 publications

References 63 publications

Gyrokinetic moment-based simulations of the Dimits shift

Gyrokinetic moment-based simulations of the Dimits shift

Moment-based approach to the flux-tube linear gyrokinetic model

Full-F turbulent simulation in a linear plasma device using a gyro-moment approach

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