Distance, Energy, and Variability of Quasar Outflows: Two HST/COS epochs of LBQS 1206+1052

Abstract

We analyze new HST/COS spectra for two quasar absorption outflows seen in the quasi-stellar object LBQS 1206+1052. These data cover, for the first time, absorption troughs from SIV, SiII, and PV. From the ratio of the SIV* to SIV column densities, we measure the electron number density of the higher-velocity (-1400 km s-1, v1400) outflow to be log(ne) = 4.23+0.09-0.09 cm-3 and constrain the lower-velocity (-730 km s-1, v700) outflow to log(ne) > 5.3 cm-3. The ne associated with the higher-velocity outflow is an order of magnitude larger than reported in prior work. We find that the previous measurement was unreliable since it was based on density-sensitive absorption troughs that were likely saturated. Using photoionization models, we determine the best 2-minimization fit for the ionization parameter and hydrogen column density of the higher-velocity outflow: log(UH) = -1.73+0.21-0.12 and log(NH) = 21.03+0.25-0.15 cm-2, respectively. We calculate from UH and ne a distance of 500+100-110 pc from the central source to the outflow. Using an SED attenuated by the v700 outflow yields a two-phase photoionization solution for the v1400 outflow, separated by a U ≈eq 0.7. Otherwise, the resultant distance, mass flux, and kinetic luminosity are similar to the unattenuated case. However, the attenuated analysis has significant uncertainties due to a lack of constraints on the v700 outflow in 2017.