Irradiation of Astrophysical Objects - SED and Flux Effects on Thermally Driven Winds

TL;DR

This paper presents a comprehensive method to model the hydrodynamics of astrophysical winds influenced by various radiation fields and SEDs, revealing complex wind behaviors and the importance of detailed photoionization calculations.

Contribution

It introduces a self-consistent approach combining photoionization and hydrodynamics for arbitrary SEDs, applied to study wind acceleration and thermal stability.

Findings

Winds reach a transonic steady state under various SEDs.

Two-stage wind acceleration occurs with multiple thermally unstable regions.

Wind dynamics strongly depend on the SED, especially soft X-ray flux.

Abstract

We develop a general method for the self consistent calculation of the hydrodynamics of an astrophysical object irradiated by a radiation field with an arbitrary strength and spectral energy distribution (SED). Using the XSTAR photoionization code, we calculate heating and cooling rates as a function of gas photoionization parameter and temperature for several examples of SEDs: bremsstrahlung, blackbody, hard and soft state XRBs, Type 1 and Type 2 AGN. As an application of our method we study the hydrodynamics of 1-dimensional spherical winds heated by a uniform radiation field using the code Athena++. We find that in all cases explored a wind settles into a transonic, steady state. The wind evolves along the radiative heating equilibrium curve until adiabatic cooling effects become important and the flow departs from radiative equilibrium. If the flow is heated very rapidly, for example as in a thermally unstable regime, the corresponding column density of gas is low. Perhaps one of the most intriguing results of our work is the two stage acceleration of the wind that happens when there are two thermally unstable regions and the flux is relatively high. The efficiency with which the radiation field transfers energy to the wind is dependent on the SED of the external source, particularly the relative flux of soft X-rays. These results suggest that detailed photoionization calculations are essential not only to predict spectra but also to properly capture the flow dynamics.