Applying Relativistic Reconnection to Blazar Jets

Abstract

Rapid and luminous flares of non-thermal radiation observed in blazars require an efficient mechanism of energy dissipation and particle acceleration in relativistic active galactic nuclei (AGN) jets. Particle acceleration in relativistic magnetic reconnection is being actively studied by kinetic numerical simulations. Relativistic reconnection produces hard power-law electron energy distributions N(gamma) = N0 gamma(-p) exp(-gamma/gammamax) with index p -> 1 and exponential cut-off Lorentz factor gammamax ~ sigma in the limit of magnetization sigma = B2/(4 pi w) >> 1 (where w is the relativistic enthalpy density). Reconnection in electron-proton plasma can additionally boost gammamax by the mass ratio mp/me. Hence, in order to accelerate particles to gammamax ~ 106 in the case of BL Lacs, reconnection should proceed in plasma of very high magnetization sigmamax >~ 103. On the other hand, moderate mean jet magnetization values are required for magnetic bulk acceleration of relativistic jets, sigmamean ~ Gammaj <~ 20 (where Gammaj is the jet bulk Lorentz factor). I propose that the systematic dependence of gammamax on blazar luminosity class -- the blazar sequence -- may result from a systematic trend in sigmamax due to homogeneous loading of leptons by pair creation regulated by the energy density of high-energy external radiation fields. At the same time, relativistic AGN jets should be highly inhomogeneous due to filamentary loading of protons, which should determine the value of sigmamean roughly independently of the blazar class.