Coupling multi-fluid dynamics equipped with Landau closures to the particle-in-cell method

Lemmerz, Rouven; Shalaby, Mohamad; Thomas, Timon; Pfrommer, Christoph

doi:10.1017/s0022377823001113

J. Plasma Phys.

2024

DOI: 10.1017/s0022377823001113

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Coupling multi-fluid dynamics equipped with Landau closures to the particle-in-cell method

Rouven Lemmerz,

Mohamad Shalaby,

Timon Thomas

et al.

Abstract: The particle-in-cell (PIC) method is successfully used to study magnetized plasmas. However, this requires large computational costs and limits simulations to short physical run times and often to set-ups of less than three spatial dimensions. Traditionally, this is circumvented either via hybrid-PIC methods (adopting massless electrons) or via magneto-hydrodynamic-PIC methods (modelling the background plasma as a single charge-neutral magneto-hydrodynamical fluid). Because both methods preclude modelling impo… Show more

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Cited by 2 publications

References 108 publications

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Deciphering the physical basis of the intermediate-scale instability

Shalaby,

Thomas,

Pfrommer

et al. 2023

J. Plasma Phys.

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We study the underlying physics of cosmic ray (CR)-driven instabilities that play a crucial role for CR transport across a wide range of scales, from interstellar to galaxy cluster environments. By examining the linear dispersion relation of CR-driven instabilities in a magnetised electron–ion background plasma, we establish that both the intermediate and gyroscale instabilities have a resonant origin, and show that these resonances can be understood via a simple graphical interpretation. These instabilities destabilise wave modes parallel to the large-scale background magnetic field at significantly distinct scales and with very different phase speeds. Furthermore, we show that approximating the electron–ion background plasma with either magnetohydrodynamics (MHD) or Hall-MHD fails to capture the fastest-growing instability in the linear regime, namely the intermediate-scale instability. This finding highlights the importance of accurately characterising the background plasma for resolving the most unstable wave modes. Finally, we discuss the implications of the different phase speeds of unstable modes on particle–wave scattering. Further work is needed to investigate the relative importance of these two instabilities in the nonlinear, saturated regime and to develop a physical understanding of the effective CR transport coefficients in large-scale CR hydrodynamics theories.

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Deciphering the physical basis of the intermediate-scale instability

Shalaby,

Thomas,

Pfrommer

et al. 2023

J. Plasma Phys.

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Energy Dissipation in Strong Collisionless Shocks: The Crucial Role of Ion-to-electron Scale Separation in Particle-in-cell Simulations

Shalaby

2024

ApJL

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Energy dissipation in collisionless shocks is a key mechanism in various astrophysical environments. Its nonlinear nature complicates analytical understanding and necessitates particle-in-cell (PIC) simulations. This study examines the impact of reducing the ion-to-electron mass ratio (m r ), to decrease computational cost, on energy partitioning in one spatial and three velocity-space dimension PIC simulations of strong, nonrelativistic, parallel electron–ion collisionless shocks using the SHARP code. We compare simulations with a reduced mass ratio (m r = 100) to those with a realistic mass ratio (m r = 1836) for shocks with high ( M A = 21.3 ) and low ( M A = 5.3 ) Alfvén Mach numbers. Our findings show that the mass ratio significantly affects particle acceleration and thermal energy dissipation. At high M A , a reduced mass ratio leads to more efficient electron acceleration and an unrealistically high ion flux at higher momentum. At low M A , it causes complete suppression of electron acceleration, whereas the realistic mass ratio enables efficient electron acceleration. The reduced mass ratio also results in excessive electron heating and lower heating in downstream ions at both Mach numbers, with slightly more magnetic field amplification at low M A . Consequently, the electron-to-ion temperature ratio is high at low M A due to reduced ion heating and remains high at high M A due to increased electron heating. In contrast, simulations with the realistic m r show that the ion-to-electron temperature ratio is independent of the upstream magnetic field, a result not observed in reduced m r simulations.

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Coupling multi-fluid dynamics equipped with Landau closures to the particle-in-cell method

Cited by 2 publications

References 108 publications

Deciphering the physical basis of the intermediate-scale instability

Deciphering the physical basis of the intermediate-scale instability

Energy Dissipation in Strong Collisionless Shocks: The Crucial Role of Ion-to-electron Scale Separation in Particle-in-cell Simulations

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