Paper detail

Ionization Modeling Astrophysical Gaseous Structures. I. The Optically Thin Regime

We present a code for modelling the ionization conditions of optically thin astrophysical gas structures. Given the gas hydrogen density, equilibrium temperature, elemental abundances, and the ionizing spectrum, the code solves the equilibrium ionization fractions and number densities for all ions from hydrogen to zinc. The included processes are photoionization, Auger ionization, direct collisional ionization, excitation auto-ionization, charge exchange ionization, two-body radiative recombination, dielectronic recombination, and charge exchange recombination. The ionizing spectrum can be generalized to include the ultraviolet background (UVB) and/or Starburst99 stellar populations of various masses, ages, metallicities, and distances. The ultimate goal with the code is to provide fast computation of the ionization conditions of gas in N-body + hydrodynamics cosmological simulations, in particular adaptive mesh refinement codes, in order to facilitate absorption line analysis of the simulated gas for comparison with observations. To this end, we developed a method to linearize the rate equations and efficiently solve the rate matrix with a minimum number of iterations. Comparing the code to Cloudy 13.03 (Ferland), we find that the hydrogen and helium ionization fractions and the metal species ionization corrections are in excellent agreement. We discuss the science drivers and plans for further development of the ionization code to a full radiative hydrodynamic routine that can be employed for processing the simulations. A stand-alone version of the code has been made publicly available (http://astronomy.nmsu.edu/cwc/Software/Ioncode/).