The extinction law at high redshift and its implications

TL;DR

This study investigates dust extinction properties in high-redshift quasars, revealing that their extinction curves differ from lower-redshift counterparts, implying different dust production mechanisms and affecting cosmic star formation estimates.

Contribution

It provides the first detailed characterization of the mean dust extinction curve at z>4, showing deviations from the SMC curve and suggesting different dust formation processes at early cosmic times.

Findings

High-redshift quasars exhibit extinction curves that deviate from the SMC curve.

The mean extinction curve at z>4 is flatter at wavelengths below 2000 Å.

Adjusting for the new extinction curve increases the estimated cosmic star formation rate by a factor of ~2.

Abstract

We analyze the optical-near infrared spectra of 33 quasars with redshifts 3.9<z<6.4 to investigate the properties of dust extinction at these cosmic epochs. The SMC extinction curve has been shown to reproduce the dust reddening of most quasars at z<2.2; we investigate whether this curve also provides a good description of dust extinction at higher redshifts. We fit the observed spectra with synthetic absorbed quasar templates obtained by varying the intrinsic slope (alpha), the absolute extinction (A3000), and by using a grid of empirical and theoretical extinction curves. We find that seven quasars in our sample are affected by substantial extinction (A3000 >0.8), and characterized by very steep intrinsic slopes (alpha<-2.3). All of the individual quasars require extinction curve deviating from that of the SMC, with a tendency to flatten at lambda<2000 A (in the rest frame of the source). We obtain a mean extinction curve at z>4, both by performing a simultaneous fit of all quasars and by averaging the extinction curves inferred for individual quasars. In the case of broad absorption line quasars the mean extinction curve deviates from the SMC at a confidence level >95%. The difference between extinction curves in quasars at z>4 and in quasars at lower redshift is indicative of either a different dust production mechanism at high redshift, or a different mechanism for processing dust into the ISM. We suggest that the same transitions may also apply to normal, star-forming galaxies at z>4. In particular, the observed change in the average spectral slope of galaxies at z>4 may be partially ascribed to a variation in the extinction curve, rather than a lower dust content at high redshift. In this scenario, the extinction curve inferred at z>4 would imply a cosmic star-formation corrected for dust attenuation a factor of ~2 higher than estimated in the past.