Variability of Broad Emission Lines in High-Luminosity,High-Redshift Quasars

TL;DR

This study investigates the variability of Lyman alpha broad emission lines in high-luminosity, high-redshift quasars, revealing observable flux changes over days to years and providing insights into the structure of their broad emission line regions.

Contribution

It presents the first significant detection of Lyman alpha BEL variability in high-luminosity, high-redshift quasars, highlighting the potential for future reverberation mapping studies.

Findings

20 quasars show >5 sigma Lyman alpha BEL variability

Variability observed over days to years in the quasar rest frame

Evidence suggests BEL regions are at similar distances from the ionizing source

Abstract

We examine the variability of the high-ionization Lyman alpha lambda 1216 broad emission line (BEL) in a sample of 61 high-luminosity, high-redshift quasars observed at two epochs by the Sloan Digital Sky Survey. These bright objects lie in the redshift interval z=[2.5, 4.3] and have luminosities $3.4 \times 10^{45} \lesssim \lambda L_{\lambda} \lesssim 3.4 \times 10^{46}$ erg/s at 1450A. Utilizing improved spectrophotometric flux calibrations relative to nearby compact stars observed simultaneously, we are able to measure the flux changes in Lyman alpha and the nearby continuum at two epochs. We find 20 objects that exhibit Lyman alpha BEL flux variability at a significance level greater than 5 sigma on time-scales ranging from days to years in the quasar rest frame. The results show that, although some earlier work showed no significant detections of Lyman alpha BEL flux changes in a quasar sample with even higher luminosity, variability is present and readily observable in the sample studied here. We also consider the CIV lambda1549 BEL. The lack of a strong correlation between Lyman alpha BEL variability and nearby continuum variability is consistent with the presence of a time lag between the variations, whereas the presence of a stronger correlation between Lyman alpha BEL variability and CIV BEL variability suggests that these BEL regions (BELRs) are at similar distances from the central ionizing source. Some interesting examples are high-lighted in the analysis, including a case where the flux of an Lyman alpha BEL increased by ~26% in 14 days in the quasar rest frame, suggesting that the BELR has the shape of a disc, which is being observed face-on. This work demonstrates that future campaigns of spectrophotometric monitoring can improve our understanding of the structure of the BELRs of high-luminosity, high-redshift quasars.