Dust Reverberation Mapping of Z229-15

TL;DR

This study uses dust reverberation mapping on galaxy Z229-15 to measure the dust torus size, revealing a smaller inner radius than expected from the radius-luminosity relation, with implications for accretion disk correction methods.

Contribution

First time dust reverberation mapping applied to Z229-15, providing detailed measurements of dust torus size and highlighting the importance of spectral index correction in such analyses.

Findings

Dust torus in Z229-15 is at 0.017 pc from the center.

Measured dust reverberation lags are consistent within errors.

Using variable spectral index affects the estimated dust radius.

Abstract

We report results of the dust reverberation mapping (DRM) on the Seyfert 1 galaxy Z229-15 at z = 0.0273. Quasi-simultaneous photometric observations for a total of 48 epochs were acquired during the period 2017 July to 2018 December in B, V, J, H and Ks bands. The calculated spectral index ({\alpha}) between B and V bands for each epoch was used to correct for the accretion disk (AD) component present in the infrared light curves. The observed {\alpha} ranges between -0.99 and 1.03. Using cross correlation function analysis we found significant time delays between the optical V and the AD corrected J, H and Ks light curves. The lags in the rest frame of the source are 12.52 (+10.00/-9.55) days (between V and J), 15.63 (+5.05/-5.11) days (between V and H) and 20.36 (+5.82/-5.68) days (between V and Ks). Given the large error bars, these lags are consistent with each other. However, considering the lag between V and Ks bands to represent the inner edge of the dust torus, the torus in Z229-15 lies at a distance of 0.017 pc from the central ionizing continuum. This is smaller than that expected from the radius luminosity (R-L) relationship known from DRM. Using a constant {\alpha} = 0.1 to account for the AD component, as is normally done in DRM, the deduced radius (0.025 pc) lies close to the expected R-L relation. However, usage of constant {\alpha} in DRM is disfavoured as the {\alpha} of the ionizing continuum changes with the flux of the source.