First black hole mass estimation for the quadruple lensed system WGD2038-4008

TL;DR

This study estimates the black hole mass in the quadruple lensed quasar WGD2038-4008 using multiple emission lines and two images, providing new insights into microlensing effects and accretion disk size.

Contribution

First estimation of black hole mass in a lensed quasar using two images and multiple emission lines, disentangling microlensing effects and measuring accretion disk size.

Findings

Black hole mass estimates around 10^8.3 to 10^8.6 solar masses.

Detected minor microlensing effects on the continuum.

Accretion disk size consistent with theoretical models.

Abstract

The quadruple lensed system WGD2038-4008 was recently discovered with the help of new techniques and observations. Even though black hole mass has been estimated for lensed quasars, it has been calculated mostly for one broad emission line of one image, but the images could be affected by microlensing, affecting the results. We present black hole mass (MBH) estimations for images A and B using the three most prominent broad emission lines (H$\alpha$, H$\beta$ and MgII) obtained in one single-epoch spectra. This is the first time the mass is estimated in a lensed quasar in two images, allowing us to disentangle the effects of microlensing. We used the X-shooter instrument mounted in VLT, to observe this system taking advantage of its wide spectral range. Using the flux ratio between the continuum and the core of the emission lines we analyzed if microlensing was present in the continuum source. We obtained MBH using the single-epoch method with the H$\alpha$ and H$\beta$ emission lines from the monochromatic luminosity and the velocity width. The luminosity at 3000 \r{A} was obtained using the Spectral Energy Distribution (SED) of image A while the luminosity at 5100 \r{A} was estimated directly from the spectra. The average MBH between the images obtained was $\rm log_{10}$(M$_{BH}/M_{\odot}$) = 8.27 $\pm$ 1.05, 8.25 $\pm$ 0.32 and 8.59 $\pm$ 0.35 for MgII, H$\beta$ and H$\alpha$ respectively. We find Eddington ratios similar to those measured in the literature for unlensed low-luminosity quasars. Microlensing of -0.16 $\pm$ 0.06 mag. in the continuum was found but the induced error in the MBH is minor compared to the one associated to the macromodel magnification. We also obtained the accretion disk size using the MBH for the three emission lines, obtaining an average value of $\rm log_{10}(r_{s}/cm)$ = 15.3 +/- 0.63, which is in agreement with theoretical estimates.