X-ray investigation of possible super-Eddington accretion in a radio-loud quasar at z=6.13

Abstract

We present radio and X-ray observations of the recently discovered z=6.13 radio-powerful quasar RACS J032021.44-352104.1 using uGMRT, ATCA, LBA, and Chandra. The observed radio properties are in line with what is typically observed in high-z radio quasars (α r=0.72 0.02 and L 1.4GHz=5.8 0.9 × 1026 W Hz-1). Despite the relatively low X-ray flux observed F 0.5-7.0 keV=2.30.5 × 10-14 erg sec-1 cm-2, the intrinsic luminosity in the 2-10 keV rest frame is markedly high, L 2-10 keV=1.8+1.1-0.7 × 1046 erg sec-1, making RACS J032021.44-352104.1 one of the most luminous quasars currently known at z>5.5. The high X-ray luminosity is largely driven by an extrapolation to energies below the observable X-ray window with Chandra and the slope derived in the 0.5-7 keV band (or 3.5--50 keV in the rest-frame; X=3.30.4). By analysing the overall spectral energy distribution of the quasar we found that the remarkably soft X-ray emission: (1) cannot be produced by relativistic jets, even when relativistic boosting is considered; and (2) is consistent with expectations for a super-Eddington accreting SMBH. If such a high accretion rate was confirmed, this source would be a unique laboratory to study high accretion in the early Universe and could help resolve some challenges inherent in early black hole growth paradigms.