The Cosmic Evolution of CIV Absorbers at $1.4<z<4.5$: Insights from $100,000$ Systems in DESI Quasars

Abstract: We present the largest catalog to \modify{date} of triply ionized carbon (CIV) absorbers detected in quasar spectra from the Dark Energy Spectroscopic Instrument. Using an automated matched-kernel convolution method with adaptive signal-to-noise thresholds, we identify $101,487$ CIV systems in the redshift range $ 1.4 < z < 4.8 $ from $300,637$ quasar spectra. Completeness is estimated via Monte Carlo simulations and catalog is $50\%$ complete at $\mathrm{EW}{\mathrm{CIV}} \geq 0.4$ Angstrom. The differential equivalent width frequency distribution declines exponentially and shows weak redshift evolution. The absorber incidence per unit comoving path increases by a factor of $2-5$ from $ z \approx 4.5 $ to $ z \approx 1.4 $, with stronger redshift evolution for strong systems. Using column densities derived from the apparent optical depth method, we constrain the cosmic mass density of CIV, $\Omega{\mathrm{CIV}}$, which increases by a factor of $\sim 3.6$ from $ (0.46 \pm 0.01) \times 10^{-8} $ at $ z \approx 4.5 $ to $ (1.65 \pm 0.04) \times 10^{-8} $ at $ z \approx 1.4 $. From $ \Omega_{\rm CIV} $, we estimate a lower limit on intergalactic medium metallicity $ \log(Z_{\rm IGM}/Z_{\odot}) \gtrsim -3.5 $ at $ z \sim 2.3 $, with a smooth decline at higher redshifts. These trends trace the cosmic star formation history and HeII photoheating rate, suggesting a link between CIV enrichment, star formation, and UV background over $\sim 3$ Gyr. The catalog also provides a critical resource for future studies connecting circumgalactic metals to galaxy evolution, especially near cosmic noon.