C IV and He II Line Emission of Lyman Alpha Blobs: Powered by Shock Heated Gas

Abstract

Utilizing ab initio ultra-high resolution hydrodynamical simulations, we investigate the properties of the interstellar and circum-galactic medium of Lyα Blobs (LABs) at z=3, focusing on three important emission lines: Lyα 1216, 1640\ and 1449. Their relative strengths provide a powerful probe of the thermodynamic properties of the gas when confronted with observations. By adjusting the dust attenuation effect using one parameter and matching the observed size-luminosity relation of LABs using another parameter, we show that our simulations can reproduce the observed /\ and /\ ratios adequately. This analysis provides the first successful physical model to account for simultaneously the LAB luminosity function, luminosity-size relation, and the /Lyα and /Lyα ratios, with only two parameters. The physical underpinning for this model is that, in addition to the stellar component for the \ emission, the \ and \ emission lines due to shock heated gas are primarily collisional excitation driven and the \ emission line collisional ionization driven. We find that the density, temperature and metallicity of the gas responsible for each emission line is significantly distinct, in a multi-phase interstellar and circumgalactic medium that is shock-heated primarily by supernovae and secondarily by gravitational accretion of gas.