A Systematic Search for X-ray Eclipse Events in Active Galactic Nuclei Observed by Swift

TL;DR

This study systematically searches for X-ray eclipse events in 40 AGNs using 20 years of Swift data, identifying several candidate clouds and exploring their properties and relation to black hole accretion.

Contribution

It is the first large-scale, systematic search for X-ray eclipse events in AGNs, revealing new insights into cloud properties and their connection to black hole accretion processes.

Findings

Identified 3 high-confidence eclipse events and 8 candidates in 40 AGNs.

Cloud properties vary with distance from the black hole and correlate with black hole mass.

Potential for future detection with the Einstein Probe X-ray monitor.

Abstract

The nuclear regions of active galactic nuclei (AGNs) likely host clumpy clouds that occasionally obscure the central X-ray source, causing eclipse events. These events offer a unique opportunity to study the properties and origins of such clouds. However, these transient events are rarely reported due to the need for extensive, long-term X-ray monitoring for years. Here, we conduct a systematic search for eclipse events in 40 AGNs well-monitored by the Swift X-ray Telescope (XRT) over the past 20 years, comprising a total of $\sim$11,000 observations. Our selection criteria rely on significant variations in X-ray flux and spectral shape. We identify 3 high-confidence events in 3 AGNs and 8 candidates in 6 AGNs, all in type I AGNs. The observed clouds have column densities of $N_{\rm H}~\sim$ (0.2 $-$ 31.2) $\times$ 10$^{22}$ cm$^{-2}$ and ionization degrees of log $\xi$ $\sim$ (-1.3 $-$ 2.2). For the 5 events with well-constrained duration, their distances from the central black hole range from (2.4 $-$ 179) $\times$ 10$^{4}$ $R_{\rm g}$, with 2 clouds near the dust sublimation zone, 2 farther out. Interestingly, we find tentative correlations between the cloud properties (i.e. ionization state and column density) and the black hole mass and mass accretion rate, implying their strong connection to the accretion process, potentially via outflows. Our study also demonstrates the potential of the new X-ray all-sky monitor, Einstein Probe, in providing more detection and physical constraints for such events.