Characterizing X-ray, UV, and optical variability in NGC 6814 using high-cadence Swift observations from a 2022 monitoring campaign

TL;DR

This study uses high-cadence Swift observations to analyze multi-wavelength variability in NGC 6814, revealing a non-standard accretion disc with inconsistent models for flux and lag spectra.

Contribution

First high-cadence UV, optical, and X-ray monitoring of NGC 6814 demonstrating non-standard accretion disc behavior through combined variability analyses.

Findings

X-ray variability is flatter than UV/optical, indicating different physical mechanisms.

UV/optical structure function break-time suggests a very compact emission region.

Lag-wavelength spectrum deviates from standard disc reprocessing models.

Abstract

We present the first results of a high-cadence Swift monitoring campaign ($3-4$ visits per day for $75$ days) of the Seyfert 1.5 galaxy NGC 6814 characterizing its variability throughout the X-ray and UV/optical wavebands. Structure function analysis reveals an X-ray power law ($\alpha=0.5^{+0.2}_{-0.1}$) that is significantly flatter than the one measured in the UV/optical bands ($\langle\alpha\rangle\approx1.5$), suggesting different physical mechanisms driving the observed variability in each emission region. The structure function break-time is consistent across the UV/optical bands ($\langle\tau\rangle\approx2.3~\mathrm{d}$), suggesting a very compact emission region in the disc. Correlated short time-scale variability measured through cross-correlation analysis finds a lag-wavelength spectrum that is inconsistent with a standard disc reprocessing scenario ($\tau\propto\lambda^{4/3}$) due to significant flattening in the optical wavebands. Flux-flux analysis finds an extremely blue AGN spectral component ($F_{\nu}\propto\lambda^{-0.85}$) that does not follow a standard accretion disc profile ($F_{\nu}\propto\lambda^{-1/3}$). While extreme outer disc truncation ($R_{\mathrm{out}}=202\pm5~r_g$) at a standard accretion rate ($\dot{m}_{\mathrm{Edd}}=0.0255\pm0.0006$) may explain the shape of the AGN spectral component, the lag-wavelength spectrum requires more modest truncation ($R_{\mathrm{out}}=1,382^{+398}_{-404}~r_g$) at an extreme accretion rate ($\dot{m}_{\mathrm{Edd}}=1.3^{+2.1}_{-0.9}$). No combination of parameters can simultaneously explain both results in a self-consistent way. Our results offer the first evidence of a non-standard accretion disc in NGC 6814.