Solving gyrokinetic systems with higher-order time dependence

Sharma, A. Y.; McMillan, B. F.

doi:10.1017/s0022377820000653

Cited by 2 publications

(1 citation statement)

References 27 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…By formally taking advantage of this improvement as part of the ordering, one may derive extended schemes that simultaneously allow gyrokinetic-ordered and drift-kinetic-ordered perturbations (Dimits 2010; McMillan & Sharma 2016). A major apparent obstacle is the appearance of time derivatives of the electric field in the dynamical equations, which requires a modified solution scheme (Sharma & McMillan 2020). In the MHD-like approach explained later in this paper, this issue has a straightforward resolution.…”

Section: Variational Theories For Drift Kinetics and Gyrokineticsmentioning

confidence: 99%

Relationship between drift kinetics, gyrokinetics and magnetohydrodynamics in the long-wavelength limit

McMillan

2023

J. Plasma Phys.

Self Cite

View full text Add to dashboard Cite

Gyrokinetic theories, even ‘global’ models, typically rely on a separation in scale (in perpendicular wavelength) between the fluctuations and the system scale. In such models direct simulation of system-scale dynamics like magnetohydrodynamic (MHD) motion is formally not consistent. Drift-kinetic theory, on the other hand, may be directly applied to model system-scale MHD-ordered behaviour. I review the long-wavelength limit of standard gyrokinetics and drift kinetics to present the relationships between these theories in an elementary fashion. This provides a pathway to global gyrokinetic modelling, resulting in an approach that is structurally similar to kinetic MHD, and I present dynamical equations for solving global field evolution in this framework. Departures from certain earlier global gyrokinetic theories include the appearance of magnetosonic (fast) modes, and the cross-coupling of the parallel and perpendicular currents with perpendicular and parallel magnetic field components. A periodic two-dimensional testcase is outlined as a benchmarking and implementation target, to help clarify practical aspects of these theories, with minimal complexity in terms of boundary conditions, and a proof-of-principle implementation of a field-solver is exhibited. To motivate this work, I first illustrate certain limitations of existing global gyrokinetic frameworks and directly identify how scale separation approximations lead to certain ‘missing’ system-scale field terms in global gyrokinetics, largely as a result of simplifications associated with the field representation in terms of $A_{\|}$ and $B_{\|}$ . As a result, the currents in the gyrokinetic Ampère's law resulting from a gyrokinetic equilibrium distribution do not match the currents implied by Ampère's law in a force-balance MHD equilibrium. I present a simple choice of equilibrium distribution function whose drift-kinetic currents are consistent with MHD currents; a specific Grad–Shafranov equilibrium is used to illustrate the size of the components of the parallel currents.

show abstract

Section: Variational Theories For Drift Kinetics and Gyrokineticsmentioning

confidence: 99%

Relationship between drift kinetics, gyrokinetics and magnetohydrodynamics in the long-wavelength limit

McMillan

2023

J. Plasma Phys.

Self Cite

View full text Add to dashboard Cite

show abstract

Global gyrokinetic study of shaping effects on electromagnetic modes at NSTX aspect ratio with ad hoc parallel magnetic perturbation effects

et al. 2022

View full text Add to dashboard Cite

Plasma shaping may have a stronger effect on global turbulence in tight-aspect-ratio tokamaks than in conventional-aspect-ratio tokamaks due to the higher toroidicity and more acute poloidal asymmetry in the magnetic field. In addition, previous local gyrokinetic studies have shown that it is necessary to include parallel magnetic field perturbations in order to accurately compute growth rates of electromagnetic modes in tight-aspect-ratio tokamaks. In this work, the effects of elongation and triangularity on global, ion-scale, linear electromagnetic modes are studied at National Spherical Torus Experiment (NSTX) aspect ratio and high plasma β using the global gyrokinetic particle-in-cell code XGC. The effects of compressional magnetic perturbations are approximated via a well-known modification to the particle drifts that was developed for flux-tube simulations [Joiner et al., Phys. Plasmas 17, 072104 (2010)], without proof of its validity in a global simulation, with the gyrokinetic codes GENE and GEM being used for local verification and global cross-verification. Magnetic equilibria are re-constructed for each distinct plasma profile that is used. Coulomb collision effects are not considered. Within the limitations imposed by the present study, it is found that linear growth rates of electromagnetic modes (collisionless microtearing modes and kinetic ballooning modes) are significantly reduced in a high-elongation and high-triangularity NSTX-like geometry compared to a circular NSTX-like geometry. For example, growth rates of kinetic ballooning modes at high- β are reduced to the level of that of collisionless trapped electron modes.

show abstract

Solving gyrokinetic systems with higher-order time dependence

Cited by 2 publications

References 27 publications

Relationship between drift kinetics, gyrokinetics and magnetohydrodynamics in the long-wavelength limit

Relationship between drift kinetics, gyrokinetics and magnetohydrodynamics in the long-wavelength limit

Global gyrokinetic study of shaping effects on electromagnetic modes at NSTX aspect ratio with ad hoc parallel magnetic perturbation effects

Contact Info

Product

Resources

About