The black hole mass of the z=2.805 multiply imaged quasar SDSS J2222+2745 from velocity-resolved time lags of the CIV emission line

Abstract

We present the first results of a 4.5 year monitoring campaign of the three bright images of multiply imaged z=2.805 quasar SDSS J2222+2745 using the Gemini North Multi-Object Spectrograph (GMOS-N) and the Nordic Optical Telescope (NOT). We take advantage of gravitational time delays to construct light curves surpassing 6 years in duration and achieve average spectroscopic cadence of 10 days during the 8 months of visibility per season. Using multiple secondary calibrators and advanced reduction techniques, we achieve percent-level spectrophotometric precision and carry out an unprecedented reverberation mapping analysis, measuring both integrated and velocity-resolved time lags for CIV. The full line lags the continuum by τ cen = 36.5+2.9-3.9 rest-frame days. We combine our measurement with published CIV lags and derive the r BLR-L relationship 10( τ / day) = (1.00 0.08) + (0.48 0.04) 10[λ Lλ(1350A)/1044~ erg ~s-1] with 0.320.06 dex intrinsic scatter. The velocity-resolved lags are consistent with circular Keplerian orbits, with τ cen = 86.2+4.5-5.0, 25+11-15, and 7.5+4.2-3.5 rest-frame days for the core, blue wing, and red wing, respectively. Using σ line with the mean spectrum and assuming 10 (f mean,σ) = 0.52 0.26, we derive 10(M BH/M) = 8.63 0.27. Given the quality of the data, this system represents a unique benchmark for calibration of M BH estimators at high redshift. Future work will present dynamical modeling of the data to constrain the virial factor f and M BH.