Bibcode
Willott, C. J.; Rawlings, Steve; Jarvis, Matt J.
Bibliographical reference
Monthly Notices of the Royal Astronomical Society, Volume 313, Issue 2, pp. 237-246.
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4
2000
Citations
32
Refereed citations
30
Description
We present near-infrared spectroscopy and imaging of the compact
steep-spectrum radio source 3C 318, which shows it to be a quasar at
redshift z=1.574 (the z=0.752 value previously reported is incorrect).
3C 318 is an IRAS, ISO and SCUBA source so its new redshift makes it the
most intrinsically luminous far-infrared (FIR) source in the 3C
catalogue (there is no evidence of strong gravitational lensing
effects). Its bolometric luminosity greatly exceeds the
1013Lsolar level above which an object is said to
be hyperluminous. Its spectral energy distribution (SED) requires that
the quasar heats the dust responsible for the FIR flux, as is believed
to be the case in other hyperluminous galaxies, and contributes (at the
>10per cent level) to the heating of the dust responsible for the
submm emission. We cannot determine whether a starburst makes an
important contribution to the heating of the coolest dust, so evidence
for a high star formation rate is circumstantial, being based on the
high dust, and hence gas, mass required by its submm detection. We show
that the current submm and FIR data available for the highest-redshift
radio galaxies are consistent with SEDs similar to that of 3C 318. This
indicates that at least some of this population may be detected in the
submm because of dust heated by the quasar nucleus, and that
interpreting submm detection as evidence for very high
(>~1000Msolaryr-1) star formation rates may not
always be valid. We show that the 3C 318 quasar is slightly reddened
(AV~0.5), the most likely cause of which is SMC-type dust in
the host galaxy. If very distant radio galaxies are reddened in a
similar way then we show that only slightly greater amounts of dust
could obscure the quasars in these sources. We speculate that the low
fraction of quasars amongst the very high redshift (z>~3) objects in
low-frequency radio-selected samples is the result of such obscuration.
The highest-z objects might be preferentially obscured because like 3C
318 they are inevitably observed very shortly after the jet-triggering
event, or because their host galaxies are richer in dust and gas at
earlier cosmic epochs, or because of some combination of these two
effects.