Abstract
ABSTRACT In large-scale optical spectroscopic surveys, there are many objects found to have multiple redshift measurements due to the weakness of their emission lines and the different automatic identification algorithms used. These include some suspicious high-redshift $(z \gtrsim 5)$ active galactic nuclei (AGNs). Here, we present a method for inspecting the high-redshift identification of such sources provided that they are radio-loud and have very long baseline interferometry (VLBI) imaging observations of their milli-arcsec (mas) scale jet structure available at multiple epochs. The method is based on the determination of jet component proper motions, and the fact that the combination of jet physics (the observed maximal values of the bulk Lorentz factor) and cosmology (the time dilation of observed phenomena in the early Universe) constrain the possible values of apparent proper motions. As an example, we present the case of the quasar J2346 + 0705 that was reported with two different redshifts, z1 = 5.063 and z2 = 0.171, in the literature. We measured the apparent proper motions (μ) of three components identified in its radio jet by utilizing VLBI data taken from 2014 to 2018. We obtained μJ1 = 0.334 ± 0.099 mas yr−1, μJ2 = 0.116 ± 0.029 mas yr−1, and μJ3 = 0.060 ± 0.005 mas yr−1. The maximal proper motion is converted to an apparent transverse speed of $\beta _{\rm app} = 41.2\pm 12.2\, c$, if the source is at redshift 5.063. This value exceeds the blazar jet speeds known to date. This and other arguments suggest that J2346 + 0705 is hosted by a low-redshift galaxy. Our method may be applicable for other high-redshift AGN candidates lacking unambiguous spectroscopic redshift determination or having photometric redshift estimates only, but showing prominent radio jets allowing for VLBI measurements of fast jet proper motions.
Highlights
The discovery of supermassive black holes (SMBHs) powering active galactic nuclei (AGNs) at redshifts higher than about 5, close to the end of the reionisation epoch, poses challenges for explaining the rapid growth of massive black holes in the early Universe (Volonteri et al 2011)
Based on the observed apparent proper motion–redshift (μ−z) relation for a large sample of AGN jets, we introduce a method that can be applied to investigate whether certain high-redshift candidate objects are at large cosmological distances, by using their radio jet proper motion measurements
We present the case of the quasar J2346+0705 as an example in Sect. 3 and discuss the possible applications and limitations of the method in Sect
Summary
The discovery of supermassive black holes (SMBHs) powering active galactic nuclei (AGNs) at redshifts higher than about 5, close to the end of the reionisation epoch, poses challenges for explaining the rapid growth of massive black holes in the early Universe (Volonteri et al 2011). In the various releases of the Sloan Digital Sky Survey (SDSS) catalogue, many objects have no spectroscopic coverage, and only their photometric redshifts are given. These include a number of (candidate) high-redshift objects. Two redshifts are reported for this object in public data bases: z1 = 5.063 in SDSS DR132 (Albareti et al 2017) adopted by NED, and z2 = 0.171 in SDSS DR163 (Ahumada, et al 2020) Based on the observed apparent proper motion–redshift (μ−z) relation for a large sample of AGN jets, we introduce a method that can be applied to investigate whether certain high-redshift candidate objects are at large cosmological distances, by using their radio jet proper motion measurements.
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