Optical spectral characterization of OP 313. Constraining the contribution of thermal and non-thermal optical emission

Abstract

The quasar OP 313 was discovered in December 2023 in very-high-energy γ rays above 100 GeV, enabling for the first time a complete characterization of its emission. However, the lack of updated measurements of its accretion disk, broad line region and dusty torus hampers a detailed interpretation of the role of accretion in the observed γ-ray production. We intend to characterize, during high-activity states, the external photon fields contributing to the IR-to-UV emission-namely dusty torus, broad line region and accretion disk-and investigate potential variability and blurring effects on the broad emission lines. We present new spectroscopic observations of OP 313 with the NOT and TNG telescopes to characterize its optical spectrum and variability with respect to archival observations from SDSS. We measure the luminosity of different broad emission lines, characterizing the broad line region, accretion disk and dusty torus. We measure the Mg II emission line, with an average flux of FMg \ II = (0.85 0.11)× 10-14 erg cm-2 s-1. Its equivalent width and luminosity are consistent with a constant line with a variable non-thermal continuum. From the stable Mg II line we derive a constant luminosity of the thermal components, (LBLR \ [erg \ s-1]) = 44.91 0.19, (Ldisk \ [erg \ s-1]) = 45.91 0.19 and (Ltorus \ [erg \ s-1]) = 44.70 0.16, and estimated a BH mass of (MBH/M)=8.36 0.18, in line with with that derived from the C III] line. These characteristics and the indicator of the accretion rate from the disk/Eddington luminosity ratio λ =LAD/LEdd = 0.23 0.10, along with a high Compton dominance, favour a FSRQ-like nature, contrary to the argued changing-look nature.