Electron and proton heating in trans-relativistic magnetic reconnection

Abstract

Hot collisionless accretion flows, such as the one in Sgr A* at our Galactic center, provide a unique setting for the investigation of magnetic reconnection. Here, protons are non-relativistic while electrons can be ultra-relativistic. By means of two-dimensional particle-in-cell simulations, we investigate electron and proton heating in the outflows of trans-relativistic reconnection (i.e., σw 0.1-1, where the magnetization σw is the ratio of magnetic energy density to enthalpy density). For both electrons and protons, we find that heating at high β i (here, β i is the ratio of proton thermal pressure to magnetic pressure) is dominated by adiabatic compression ('adiabatic heating'), while at low β i it is accompanied by a genuine increase in entropy ('irreversible heating'). For our fiducial σw=0.1, the irreversible heating efficiency at β i 1 is nearly independent of the electron-to-proton temperature ratio T e/T i (which we vary from 0.1 up to 1), and it asymptotes to 2\% of the inflowing magnetic energy in the low-β i limit. Protons are heated more efficiently than electrons at low and moderate β i (by a factor of 7), whereas the electron and proton heating efficiencies become comparable at β i 2 if T e/T i=1, when both species start already relativistically hot. We find comparable heating efficiencies between the two species also in the limit of relativistic reconnection (σw 1). Our results have important implications for the two-temperature nature of collisionless accretion flows, and may provide the sub-grid physics needed in general relativistic MHD simulations.