Hintze Centre for Astrophysical Surveys

Theory of pixel lensing towards M31 I: the density contribution and mass of MACHOs

(2000)

Authors:

E Kerins, BJ Carr, NW Evans, P Hewett, E Lastennet, Y Le Du, A-L Melchior, SJ Smartt, D Valls-Gabaud

Discovery of Circularly Polarized Radio Emission from SS 433.

The Astrophysical journal 530:1 (2000) L29-L32

Authors:

R Fender, D Rayner, R Norris, RJ Sault, G Pooley

Abstract:

We report the discovery of circularly polarized radio emission from the radio-jet X-ray binary SS 433 with the Australia Telescope Compact Array. The flux density spectrum of the circular polarization, clearly detected at four frequencies between 1 and 9 GHz, is of the form V~nu-0.9+/-0.1. Multiple components in the source and a lack of very high spatial resolution do not allow a unique determination of the origin of the circular polarization or of the spectrum of fractional polarization. However, we argue that the emission is likely to arise in the inner regions of the binary, possibly via propagation-induced conversion of linear to circular polarization, and the fractional circular polarization of these regions may be as high as 10%. Observations such as these have the potential to help us investigate the composition, whether pairs or baryonic, of the ejecta from X-ray binaries.

The radio luminosity of persistent X-ray binaries

(2000)

Authors:

RP Fender, MA Hendry

Correlated X-ray Spectral and Timing Behavior of the Black Hole Candidate XTE J1550-564: A New Interpretation of Black Hole States

(2000)

Authors:

Jeroen Homan, Rudy Wijnands, Michiel van der Klis, Tomaso Belloni, Jan van Paradijs, Marc Klein-Wolt, Rob Fender, Mariano Mendez

Infrared spectrum of an extremely cool white-dwarf star

Nature 403:6765 (2000) 57-59

Authors:

ST Hodgkin, BR Oppenheimer, NC Hambly, RF Jameson, SJ Smartt, IA Steele

Abstract:

White dwarfs are the remnant cores of stars that initially had masses of less than 8 solar masses. They cool gradually over billions of years, and have been suggested to make up much of the 'dark matter' in the halo of the Milky Way. But extremely cool white dwarfs have proved difficult to detect, owing to both their faintness and their anticipated similarity in colour to other classes of dwarf stars. Recent improved models indicate that white dwarfs are much more blue than previously supposed, suggesting that the earlier searches may have been looking for the wrong kinds of objects. Here we report an infrared spectrum of an extremely cool white dwarf that is consistent with the new models. We determine the star's temperature to be 3,500 +/- 200 K, making it the coolest known white dwarf. The kinematics of this star indicate that it is in the halo of the Milky Way, and the density of such objects implied by the serendipitous discovery of this star is consistent with white dwarfs dominating the dark matter in the halo.