The Low-z Intergalactic Medium. II. LyB, OVI, and CIII Forest
Abstract
We present the results of a large survey of HI, OVI, and CIII absorption lines in the low-redshift (z<0.3) intergalactic medium (IGM). We begin with 171 strong Lyalpha absorption lines (W>80 mA) in 31 AGN sight lines studied with the Hubble Space Telescope and measure corresponding absorption from higher-order Lyman lines with FUSE. Higher-order Lyman lines are used to determine NHI and bHI accurately through a curve-of-growth (COG) analysis. We find that the number of HI absorbers per column density bin is a power-law distribution, dN/dNHI=N-beta, with betaHI=1.68+-0.11. We made 40 detections of OVI 1032,1038 and 30 detections of CIII 977 out of 129 and 148 potential absorbers, respectively. The column density distribution of CIII absorbers has betaCIII=1.68+-0.04, similar to betaHI but not as steep as betaOVI=2.1+-0.1. From the absorption-line frequency, dNCIII/dz=12+3-2 for W(CIII)>30 mA, we calculate a typical IGM absorber size r0~400 kpc. The COG-derived b-values show that HI samples material with T<105 K, incompatible with a hot IGM phase. By calculating a grid of CLOUDY models of IGM absorbers with a range of collisional and photoionization parameters, we find it difficult to simultaneously account for the OVI and CIII observations with a single phase. The observations require a multiphase IGM in which HI and CIII arise in photoionized regions, while OVI is produced primarily through shocks. From the multiphase ratio NHI/NCIII, we infer the IGM metallicity ZC=0.12 Zsun, similar to our previous estimate of ZO=0.09 Zsun from OVI.
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