Structured, relativistic jets driven by radiation

TL;DR

This paper derives analytic solutions for structured, relativistic jets driven by radiation in hyperaccreting systems, revealing how radiation influences jet structure and Lorentz factor profiles.

Contribution

It presents the first analytic solutions to radiation hydrodynamics equations describing structured relativistic jets with a core and sheath, driven entirely by radiation.

Findings

Jets can have Gaussian or steeper Lorentz factor profiles depending on ambient medium

Outer sheath contains most of the jet mass

Radiation can sustain jet structure without magnetic fields

Abstract

Relativistic jets, or highly collimated and fast-moving outflows, are endemic to many astrophysical phenomena. The jets produced by gamma-ray bursts and tidal disruption events are accompanied by the accretion of material onto a black hole or neutron star, with the accretion rate exceeding the Eddington limit of the compact object by orders of magnitude. In such systems, radiation dominates the energy-momentum budget of the outflow, and the dynamical evolution of the jet is governed by the equations of radiation hydrodynamics. Here we show that there are analytic solutions to the equations of radiation hydrodynamics in the viscous (i.e., diffusive) regime that describe structured, relativistic jets, which consist of a fast-moving, highly relativistic core surrounded by a slower-moving, less relativistic sheath. In these solutions, the slower-moving, outer sheath contains most of the mass, and the jet structure is mediated by local anisotropies in the radiation field. We show that, depending on the pressure and density profile of the ambient medium, the angular profile of the jet Lorentz factor is Gaussian or falls off even more steeply with angle. These solutions have implications for the nature of jet production and evolution in hyperaccreting systems, and demonstrate that such jets -- and the corresponding jet structure -- can be sustained entirely by radiative processes. We discuss the implications of these findings in the context of jetted tidal disruption events and short and long gamma-ray bursts.