Emission-line Variable Active Galactic Nuclei at Cosmic Noon from HETDEX

TL;DR

This study provides the first statistical analysis of emission-line variable active galactic nuclei at cosmic noon, revealing their incidence, variability timescales, Baldwin effect behavior, and Eddington ratio tendencies, advancing understanding of AGN evolution.

Contribution

It introduces a homogeneous sample of 100 EVA at z~1.5, characterizes their variability, and uncovers evolving Baldwin effect behaviors, offering new insights into AGN emission-line variability during peak black hole growth.

Findings

Incidence fraction of EVA is approximately 0.9%.

Characteristic variability timescales are around 2-3 years.

Many EVA exhibit both Baldwin effect and anti-Baldwin effect behaviors.

Abstract

We present the first statistical census of emission-line variable active galactic nuclei (EVA) at cosmic noon by combining untargeted and deep HETDEX spectroscopy with multi-epoch spectra from SDSS, DESI, and LAMOST. Anchoring all candidates to a HETDEX spectroscopic epoch and requiring AGN classification in either the HETDEX or the external epoch(s), we identify a homogeneous sample of 100 EVA at z~1.5, including 98 newly identified. Emission-line variability is selected primarily through statistically significant line-flux changes, supplemented by extensive visual inspections using contemporaneous photometric light curves. The resulting incidence fraction is $f_{\rm EVA} \approx 0.9\%$. The rest-frame intervals between spectroscopic epochs span $\sim$1--10 yr, with brightening and dimming events exhibiting statistically indistinguishable characteristic timescales ($\Delta T\sim2.2$ and $\sim2.6$ yr, respectively). A key result is the characterization of the Baldwin effect in the time domain: while many EVA follow the ensemble Baldwin effect (eBeff) between two epochs, a substantial fraction exhibit apparent anti-eBeff responses. Time-resolved spectroscopy of an individual source reveals that the intrinsic EW--luminosity relation is non-stationary, with the line-to-continuum responsivity systematically evolving from stronger to weaker across successive variability cycles; sparse two-epoch sampling of this evolving intrinsic Baldwin evolution (iBeff) naturally produces both eBeff-like and anti-eBeff behaviors. Finally, EVA show no strong preference for extreme Eddington ratios but exhibit a mild tendency toward lower $\lambda_{\rm Edd}$ values relative to matched control samples, driven primarily by sources observed in their dim states. Together, these results establish a coherent framework for interpreting emission-line variability in AGN at the peak epoch of cosmic black hole growth.