A leptonic jet model with stochastic turbulent acceleration predicts hard and soft X-ray Fourier lags plus a transition regime in HBLs, with STA and nonlinear SSC cooling amplifying lags and explaining trends with flare duration.
Acceleration of Relativistic Electrons by MHD Turbulence: Implications for Non-thermal Emission from Black Hole Accretion Disks
1 Pith paper cite this work. Polarity classification is still indexing.
abstract
We use analytic estimates and numerical simulations of test particles interacting with magnetohydrodynamic (MHD) turbulence to show that subsonic MHD turbulence produces efficient second-order Fermi acceleration of relativistic particles. This acceleration is not well-described by standard quasi-linear theory but is a consequence of resonance broadening of wave-particle interactions in MHD turbulence. We provide momentum diffusion coefficients that can be used for astrophysical and heliospheric applications and discuss the implications of our results for accretion flows onto black holes. In particular, we show that particle acceleration by subsonic turbulence in radiatively inefficient accretion flows can produce a non-thermal tail in the electron distribution function that is likely important for modeling and interpreting the emission from low luminosity systems such as Sgr A* and M87.
fields
astro-ph.HE 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
citing papers explorer
-
X-ray Fourier lag-frequency spectra modulated by stochastic turbulent acceleration in the jets of high-frequency-peaked BL Lac
A leptonic jet model with stochastic turbulent acceleration predicts hard and soft X-ray Fourier lags plus a transition regime in HBLs, with STA and nonlinear SSC cooling amplifying lags and explaining trends with flare duration.