Evolution of CIV Absorbers I. The Cosmic Incidence

Abstract

We present a large high-resolution study of the distribution and evolution of CIV absorbers, including the weakest population with equivalent widths Wr<0.3~. By searching 369 high-resolution, high signal-to-noise spectra of quasars at 1.1≤ zem ≤5.3 from Keck/HIRES and VLT/UVES, we find 1268 CIV absorbers with Wr ≥ 0.05~ (our 50\% completeness limit) at redshifts 1≤ z ≤4.75. A Schechter function describes the observed equivalent width distribution with a transition from power-law to exponential decline at Wr 0.5~. The power-law slope α rises by 7\% and transition equivalent width W falls by \!20\% from z =1.7 to z =3.6. We find that the co-moving redshift path density, dN/dX, of Wr ≥ 0.05~ absorbers rises by 1.8 times from z 4.0 to z 1.3, while the Wr ≥ 0.6~ dN/dX rises by a factor of 8.5. We quantify the observed evolution by a model in which dN/dX decreases linearly with redshift. The model suggests that populations with larger Wr thresholds evolve faster with redshift and appear later in the universe. The cosmological Technicolor Dawn simulations at z=3-5 over-produce the observed abundance of absorbers with Wr<0.3~, while yielding better agreement at higher Wr. Our empirical linear model successfully describes CIV evolution in the simulations and the observed evolution of Wr ≥ 0.6~ CIV for the past 12 Gyr. Combining our measurements with the literature gives us a picture of CIV-absorbing structures becoming more numerous and/or larger in physical size over the last ≈13 Gyr of cosmic time (z6 to z0).