Robotic Reverberation Mapping of the Southern Seyfert NGC 3783

TL;DR

This study uses spectroscopic and photometric monitoring to measure time delays in emission lines of NGC 3783, leading to a refined black hole mass estimate and insights into the broad-line region dynamics.

Contribution

It provides improved reverberation mapping measurements of NGC 3783 with higher sampling rate, reducing uncertainties and enabling velocity-resolved analysis for more accurate black hole mass determination.

Findings

Black hole mass estimated at 2.34 million solar masses.

Significant reduction in measurement uncertainties (~50%).

Detection of velocity-resolved time delays across Hβ profile.

Abstract

We present spectroscopic and photometric monitoring of NGC 3783 conducted throughout the first half of 2020. Time delays between the continuum variations and the response of the broad optical emission lines were clearly detected, and we report reverberation measurements for H$\beta$, HeII $\lambda 4686$, H$\gamma$, and H$\delta$. From the time delay in the broad H$\beta$ emission line and the line width in the variable portion of the spectrum, we derive a black hole mass of $M_{\rm BH} = 2.34^{+0.43}_{-0.43} \times 10^7$ M$_{\odot}$. This is slightly smaller than, but consistent with, previous determinations. However, our significantly improved time sampling ($T_{\rm med}=1.7$ days compared to $T_{\rm med}=4.0$ days) has reduced the uncertainties on both the time delay and the derived mass by $\sim 50$%. We also detect clear velocity-resolved time delays across the broad H$\beta$ profile, with shorter lags in the line wings and a longer lag in the line core. Future modeling of the full velocity-resolved time delay response will further improve the reverberation-based mass for NGC 3783, adding it to the small but growing sample of AGNs for which we have direct, primary black hole mass measurements. Upcoming MUSE observations at VLT will also allow NGC 3783 to join the smaller sample of black holes where reverberation masses and masses from stellar dynamical modeling may be directly compared.