Cosmology

The UVX quasar optical luminosity function and its evolution

MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY 293:1 (1998) 107-112

Authors:

P Goldschmidt, L Miller

The ages and metallicities of early-type galaxies in the Fornax cluster

MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY 295:2 (1998) L29-L33

Authors:

H Kuntschner, RL Davies

The AAO 2dF QSO Redshift Survey

ArXiv astro-ph/9710202 (1997)

Authors:

Boyle, RJ Smith, T Shanks, SM Croom, L Miller

Abstract:

We describe the aims, strategy and status of the AAO 2dF QSO redshift survey. This goal of the survey is to obtain redshifts for 30000 QSOs in a homogeneous magnitude limited (B<21) survey. The survey began in early 1997 and should be complete by the end of 1999.

Detection of a Cosmic Microwave Background Decrement toward the z = 3.8 Quasar Pair PC 1643+4631A, B

The Astrophysical Journal American Astronomical Society 479:1 (1997) l1-l3

Authors:

Michael E Jones, Richard Saunders, Joanne C Baker, Garret Cotter, Alastair Edge, Keith Grainge, Toby Haynes, Anthony Lasenby, Guy Pooley, Huub Röttgering

Optical and infrared investigation toward the z = 3.8 quasar pair PC 1643+4631A, B

Astrophysical Journal Letters 479:1 (1997) L5-L8

Authors:

R Saunders, JC Baker, MN Bremer, AJ Bunker, G Cotter, S Eales, K Grainge, T Haynes, ME Jones, M Lacy, G Pooley, S Rawlings

Abstract:

In a companion Letter, Jones et al. report the discovery of a cosmic microwave background decrement, indicative of a distant cluster with mass ∼1015 M⊙, toward the quasar pair PC 1643+4631A, B (z = 3.79, 3.83, separation 1980). To search for the cluster responsible, we have obtained R-, J-, and K-band images of the field and have also carried out optical spectroscopy of selected objects in it. No such cluster is evident in these images. Assuming that the cluster causing the decrement is similar to massive clusters already known, our magnitude limits imply that it must lie at about or beyond z = 1. This provides independent support for the X-ray-based distance argument of Jones et al. The cluster must gravitationally lens objects behind it; for a cluster z around 1-2, the Einstein ring radius for sources at z ≈ 3.8 is ∼100″. Simple modeling, producing simultaneously the Sunyaev-Zeldovich effect and the lensing, shows that the source positions of quasars A and B lie within 1100 of each other and may indeed be coincident. The two quasar spectra are found to be remarkably similar apart from their 1% redshift difference. Assuming that A and B are images of a single quasar, we present a possible explanation of this difference.