Linearised Fokker–Planck collision model for gyrokinetic simulations

Journal article

We introduce a gyrokinetic, linearised Fokker–Planck collision model that satisfies conservation laws and is accurate at arbitrary collisionalities. The differential test-particle component of the operator is exact; the integral field-particle component is approximated using a spherical harmonic and a modified Laguerre polynomial expansion developed by Hirshman and Sigmar (1976 Phys. Fluids 19 1532). The numerical methods of the implementation in the δf-gyrokinetic code stella (Barnes et al 2019 J. Comput. Phys. 391 365–80) are discussed, and conservation properties of the operator are demonstrated. The collision model is then benchmarked against the collision model of the gyrokinetic solver GS2 in the limiting cases of a reduced test-particle collision operator and energy- and momentum-conserving operator. The accuracy of the full collision model is investigated by solving the parallel Spitzer-Härm problem for the transport coefficients. It is shown that retaining collisional energy flux and higher-order terms in the field-particle operator reduces errors in the transport coefficients from 10%–25% for a simple momentum- and energy-conserving model to under 1%.

Authors: von Boetticher, A; Parra, FI; Barnes, M

• Publication status: Published
• Peer review status: Peer reviewed
• Publisher: IOP Publishing
• Journal: Plasma Physics and Controlled Fusion
• Volume: 66
• Issue: 10
• Article number: 105016
• Publication date: 2024-09-09
• Acceptance date: 2024-08-07
• DOI: 10.1088/1361-6587/ad6c7c
• EISSN: 1361-6587
• ISSN: 0741-3335
• Language: English
• Keywords: turbulence; magnetic confinement fusion; Fokker–Planck operator; gyrokinetics; stellarator