Spectrophotometric reverberation mapping of Intermediate-mass black hole NGC 4395

TL;DR

This study uses spectrophotometric reverberation mapping to measure the size of the broad line region and estimate the black hole mass in the low-luminosity galaxy NGC 4395, providing new insights into intermediate-mass black holes.

Contribution

It presents the first detailed reverberation mapping of NGC 4395 using optical telescopes, accurately measuring the Hα lag and black hole mass for this IMBH.

Findings

Hα lag measured at approximately 125 minutes.

Black hole mass estimated at about 2.2 x 10^4 solar masses.

Eddington ratio of the black hole is 0.06.

Abstract

Understanding the origins of massive black hole seeds and their co-evolution with their host galaxy requires studying intermediate-mass black holes (IMBHs) and estimating their mass. However, measuring the mass of these IMBHs is challenging due to the high spatial resolution requirement. A spectrophotometric reverberation monitoring is performed for a low-luminosity Seyfert 1 galaxy NGC 4395 to measure the size of the broad line region (BLR) and black hole mass. The data were collected using the 1.3-m Devasthal fast optical telescope (DFOT) and 3.6-m Devasthal optical telescope (DOT) at ARIES, Nainital, over two consecutive days in March 2022. The analysis revealed strong emission lines in the spectra and light curves of merged 5100{\AA} spectroscopic continuum flux ($f_{\mathrm{5100}}$) with photometric continuum V-band and H$\alpha$, with fractional variabilities of 6.38\% and 6.31\% respectively. In comparison to several previous studies with lag estimation $<$ 90 minutes, our calculated H$\alpha$ lag supersedes by $125.0^{+6.2}_{-6.1}$ minutes using ICCF and {\small JAVELIN} methods. The velocity dispersion ($\sigma_{\mathrm{line}}$) of the broad line clouds is measured to be $544.7^{+22.4}_{-25.1}$ km s$^{-1}$, yielding a black hole mass of $\sim$ $2.2^{+0.2}_{-0.2}\times 10^{4}M_{\mathrm{\odot}}$ and an Eddington ratio of 0.06.