Anisotropic heating and parallel heat flux in electron-only magnetic reconnection with intense guide fields Article Swipe

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Physics Magnetic reconnection Anisotropy Electron Magnetic field Heat flux Plasma Condensed matter physics Magnetic flux Flux (metallurgy) Gyrokinetics Electron temperature Computational physics Quantum electrodynamics Mechanics Nuclear physics Heat transfer Tokamak Quantum mechanics Materials science Metallurgy

Jincai Ren , Giuseppe Arrò , Maria Elena Innocenti , Giovanni Lapenta ·

YOU? · · 2025 · Open Access · · DOI: https://doi.org/10.1017/s0022377825100548 · OA: W4412551061

Electron-only reconnection (E-REC) is a process recently observed in the Earth’s magnetosheath, where magnetic reconnection occurs at electron kinetic scales, and ions do not couple to the reconnection process. Electron-only reconnection is likely to have a significant impact on the energy conversion and dissipation of turbulence cascades at kinetic scales in some settings. This paper investigates E-REC under different intensities of strong guide fields (the ratio between the guide field and the in-plane asymptotic field strength is 5, 10 and 20, respectively) via two-dimensional fully kinetic particle-in-cell simulations, focusing on electron heating. The simulations are initialized with a force-free current sheet equilibrium under various intensities of strong guide fields. Similarly to previous experimental studies, electron temperature anisotropy along separatrices is observed, which is found to be mainly caused by the variations of parallel temperature. Both regions of anisotropy and parallel temperature increase/decrease along separatrices become thinner with increasing guide fields. Besides, we find a transition from a quadrupolar to a hexapolar (six-polar) to an octopolar (eight-polar) structure in temperature anisotropy and parallel temperature as the guide field intensifies. Non-Maxwellian electron velocity distribution functions (EVDFs) at different locations in the three simulations are observed. Our results show that parallel electron velocity varies notably with different guide field intensities and finite parallel electron heat flux density is observed. The three simulations exhibit features of the Chew–Goldberger–Low theory, with the level of consistency increasing as the guide field strength increases. This explains the electron parallel temperature variations and the shape of the EVDFs observed along the separatrices. This work may provide insights into the understanding of electron heating and parallel heat flux density in E-REC observed in the turbulent magnetosheath.