A jet formation model for astrophysical objects

TL;DR

This paper introduces a unified model explaining jet formation across various astrophysical objects, emphasizing turbulence-driven energy storage in accretion disks leading to jet ejection.

Contribution

The model uniquely links turbulence energy fraction to jet formation, applicable to diverse systems like AGN, YSOs, and X-ray binaries.

Findings

Jets originate from the innermost thick disk regions.

A turbulence energy fraction  > 0.5 is necessary for jet formation.

The model unifies jet formation mechanisms across different astronomical objects.

Abstract

We propose a unified model for jet formation applicable to active galactic nuclei, young stellar objects, and X-ray binaries. In this model, the binding energy released from the accretion disk is primarily stored as turbulence rather than being radiated away, leading to the formation of advection-dominated accretion flows. Near the central object, a thick accretion disk with funnel-like structures develops. Within the turbulent flows, the smallest stable blobs can be accelerated beyond the escape velocity through the combination of two mechanisms - the Gaussian-like velocity distribution within the turbulence and a mechanism involving the combined effects of inward pressure force and angular momentum conservation.These rapidly moving blobs may exit through the funnels, collectively forming two opposing jets. This model predicts that jets originate from the innermost region of the thick disk surrounding the central object. The formation of jet is directly related a parameter \eta that describes the energy fraction stored in turbulence in units of the binding energy of local Keplerian energy. \eta > 0.5 is a minimal condition for jet to form. This model can be extended to account for jet formation in active galactic nuclei, young stellar objects, X-ray binaries, and other analogous astronomical systems.