Spectral properties and energy transfer at kinetic scales in collisionless plasma turbulence

TL;DR

This study uses kinetic simulations to analyze spectral properties and energy transfer mechanisms in collisionless plasma turbulence, revealing electron-driven processes and specific spectral laws at kinetic scales.

Contribution

It uncovers an indirect electron-driven energy transfer mechanism and characterizes spectral laws at kinetic scales in collisionless plasma turbulence.

Findings

Magnetic field spectrum follows a specific exponential power law at kinetic scales.

Electrons dominate the energy transfer to magnetic fields at kinetic scales.

An electron-driven energy transfer mechanism efficiently channels energy from large to sub-ion scales.

Abstract

By means of a fully kinetic simulation of freely decaying plasma turbulence, we study the spectral properties and the energy exchanges characterizing the turbulent cascade in the kinetic range. We find that the magnetic field spectrum follows the ${k^{-\alpha}\,exp(-\lambda\, k)}$ law at kinetic scales with $\alpha\!\simeq\!2.73$ and $\lambda\!\simeq\!\rho_e$ (where ${\rho_e}$ is the electron gyroradius). The same law with $\alpha\!\simeq\!0.94$ and an exponential decay characterized by $\lambda\!\simeq\!0.87\rho_e$ is observed in the electron velocity spectrum but not in the ion velocity spectrum that drops like a steep power law $\sim k^{-3.25}$ before reaching electron scales. By analyzing the filtered energy conversion channels, we find that the electrons play a major role with respect to the ions in driving the magnetic field dynamics at kinetic scales. Our analysis reveals the presence of an indirect electron-driven mechanism that channels the e.m. energy from large to sub-ion scale more efficiently than the direct nonlinear scale-to-scale transfer of e.m. energy. This mechanism consists of three steps: in the first step the e.m. energy is converted into electron fluid flow energy at large scales; in the second step the electron fluid flow energy is nonlinearly transferred towards sub-ion scales; in the final step the electron fluid flow energy is converted back into e.m. energy at sub-ion scales. This electron-driven transfer drives the magnetic field cascade up to fully developed turbulence, after which dissipation becomes dominant and the electrons start to subtract energy from the magnetic field and dissipate it via the pressure-strain interaction at sub-ion scales.