How the diffuse Universe cools

TL;DR

This study investigates how diffuse gas in the universe cools by analyzing emission lines and continuum radiation, highlighting the dominant wavelengths, elements, and ions involved, and emphasizing the importance of UV emission.

Contribution

It provides a detailed analysis of the wavelengths, elements, and ions responsible for cooling diffuse gas across cosmic time using cosmological simulations.

Findings

Most energy emitted as lines at z=0 and z=2

Hydrogen lines dominate line emission, especially Lyman series

UV band (100-4000 Å) is the primary emission range

Abstract

In this work we investigate the cooling channels of diffuse gas (i.e. n_H<0.1 cm^-3) in cosmology. We aim to identify the wavelengths where most of the energy is radiated in the form of emission lines or continuum radiation, and the main elements and ions responsible for the emission. We use a subset of cosmological, hydrodynamical runs from the OWLS project to calculate the emission of diffuse gas and its evolution with time. We find that at z=0 (z=2) about 70 (80) per cent of the energy emitted by diffuse gas is carried by emission lines, with the continuum radiation contributing the remainder. Hydrogen lines in the Lyman series are the primary contributors to the line emission, with a share of 16 (20) per cent. Oxygen lines are the main metal contributors at high redshift, while silicon, carbon and iron lines are strongest at low redshift, when the contributions of AGB stars and supernova Ia explosions to the metal budget become important and when there is more hot gas. The ionic species carrying the most energy are OIII, CII, CIII, SiII, SiIII, FeII and SIII. The great majority of energy is emitted in the UV band (lambda=100-4000 A), both as continuum radiation and line emission. With almost no exception, all the strongest lines fall in this band. At high energies, continuum radiation is dominant (e.g., 80 per cent in the X-ray band), while lines contribute progressively more at lower energies. While the results do depend on the details of the numerical implementation of the physical processes modelled in the simulations, the comparison of results from different simulations demonstrates that the variations are overall small, and that the conclusions are fairly robust. Given the overwhelming importance of UV emission for the cooling of diffuse gas, it is desirable to build instruments dedicated to the detection and characterisation of diffuse UV emission.