Varstrometry for Off-nucleus and Dual sub-Kpc AGN (VODKA): Long-slit optical spectroscopic follow-up with Gemini/GMOS and HST/STIS

TL;DR

This study uses high-resolution optical spectroscopy from Gemini and HST to identify and confirm dual and lensed quasars among candidates, revealing a significant contamination rate and emphasizing the importance of quality spectral data for accurate identification.

Contribution

First spectroscopic follow-up of Gaia-selected dual quasar candidates demonstrating the effectiveness of combined spectral and color data in identifying true dual quasars.

Findings

41-67% star contamination rate without prior selection

Dual/lensed quasar fraction ≥26% in the sample

Dual/lensed quasar fraction ≥67% with combined spectral and color cuts

Abstract

High spatial and spectral resolution observations are essential for identifying sub-arcsecond dual and lensed quasars and confirming their redshifts. We present Gemini/GMOS and HST/STIS optical spectra for 27 dual quasar candidates selected based on their variability-induced astrometric noise or double detections in Gaia (the VODKA project). From this follow-up, we spectroscopically identify 11 star superpositions and 7 dual/lensed quasars. Among the remaining targets, 2 are likely dual/lensed quasars based on additional radio imaging, while the rest are quasars with unknown companions. Without prior photometric or spectroscopic selection, we find the star contamination rate to be 41-67%, while the dual/lensed quasar fraction is $\gtrsim$ 26% in the follow-up VODKA sample. However, when combined with existing unresolved spectra and spatially-resolved two-band color cuts, the dual/lensed quasar fraction can be increased to $\gtrsim$ 67%. Our study highlights the need for high-quality spectral data, including a signal-to-noise ratio of at least 20, spatial resolution that is at least twice finer than the source separation, and a spectral resolution of $R \gtrsim 1000$, in order to separate close sources, exclude stellar superpositions, and reliably identify dual quasars.