The Great Slump: Mrk926 reveals discrete and varying Balmer line satellite components during a drastic phase of decline

TL;DR

This study of Mrk926, a highly variable AGN, reveals complex broad-line region structures, including satellite components, and measures a black hole mass of approximately 110 million solar masses during a significant decline phase.

Contribution

It provides the first detailed velocity-resolved reverberation mapping of Mrk926, identifying discrete satellite components and their spatial origins, and measures the black hole mass during a drastic luminosity decline.

Findings

Drastic continuum luminosity decrease to less than 50% in 2.5 months.

Detection of broad Balmer satellite components responding within 3-5 days.

Black hole mass estimated at approximately 1.1 x 10^8 solar masses.

Abstract

Mrk926 is known to be a highly variable AGN with very broad line profiles. We studied the continuum and line profile variations of this object with high temporal resolution in order to determine its broad-line region structure and to derive its BH mass. We carried out a high-cadence spectroscopic variability campaign of Mrk926 with the 10m HET telescope, aided by photometric V-band data taken at the Wise Observatory, over a period of about five months. We extracted spectroscopic continuum and line light curves, and computed CCFs as well as velocity-resolved CCFs with respect to the combined continuum V-band light curve. The continuum luminosity of Mrk926 showed a drastic decrease during our campaign: it dropped to less than 50% of its original value within only 2.5 months. The spectra show complex and very broad Balmer line profiles, including outer Balmer satellites ranging from +-5000 to +-13,000 kms-1. The Ha, Hb, and HeI5876 line light curves are delayed relative to the continuum light curve. The Ha and Hb lines show two velocity-delay structures in the central part of their line profile (within +- 5000 kms-1), at ~10 and ~57 ld and at ~5 and ~48 ld, respectively. These structures might be interpreted as the signature of a line-emitting ring, inclined by ~50 deg to the line of sight and orbiting the BH at radii, R, of 33.5 and 26.5 ld. We determined continuum luminosities, log(lambda\,L_(lambda)/erg s-1), of 43.68 to 44.13, which are in good agreement with the established R_(BLR)-L_(AGN) relation. We derive a black hole mass of 1.1 +- 0.2 * 10^8 M_solar; this indicates a low Eddington ratio, which decreased from 8 to 3 percent during our campaign. The Balmer satellite components show a response to the continuum variations on the order of only 3-5 days. We attribute this to the central line segment and the Balmer satellites having different, spatially distinct regions of origin.