MeerKAT

The variable radio-to-x-ray spectrum of the magnetar XTE J1810-197

Astrophysical Journal 669:1 (2007) 561-569

Authors:

F Camilo, SM Ransom, J Peñalver, A Karastergiou, MH Van Kerkwijk, M Durant, JP Halpern, J Reynolds, C Thum, DJ Helfand, N Zimmerman, I Cognard

Abstract:

We have observed the 5.54 s anomalous X-ray pulsar XTE J1810-197at radio, millimeter, and infrared (IR) wavelengths, with the aim of learning about its broadband spectrum. At the IRAM 30 m telescope, we have detected the magnetar at ν = 88 and 144 GHz, the highest radio-frequency emission ever seen from a pulsar. At 88 GHz we detected numerous individual pulses, with typical widths ∼2 ms and peak flux densities up to 45 Jy. Together with nearly contemporaneous observations with the Parkes, Nançay, and Green Bank telescopes, we find that in late 2006 July the spectral index of the pulsar was -0.5 ≲ α ≲ 0 (with flux density Sν ∝ να) over the range 1.4-144 GHz. Nine dualfrequency Very Large Array and Australia Telescope Compact Array observations in 2006 May-September are consistent with this finding, while showing variability of α with time. We infer from the IRAM observations that XTE J1810-197 remains highly linearly polarized at millimeter wavelengths. Also, toward this pulsar, the transition frequency between strong and weak scattering in the interstellar medium may be near 50 GHz. At Gemini, we detected the pulsar at 2,2 μm in 2006 September, at the faintest level yet observed, Ks = 21.89 ± 0.15. We have also analyzed four archival IR Very Large Telescope observations (two unpublished), finding that the brightness fluctuated within a factor of 2-3 over a span of 3 years, unlike the monotonie decay of the X-ray flux. Thus, there is no correlation between IR and X-ray flux, and it remains uncertain whether there is any correlation between IR and radio flux. © 2007. The American Astronomical Society. All rights reserved.

The High-Energy Emission of GRO J1655–40 As Revealed with INTEGRAL Spectroscopy of the 2005 Outburst

The Astrophysical Journal American Astronomical Society 669:1 (2007) 534-545

Authors:

MD Caballero García, JM Miller, E Kuulkers, M Díaz Trigo, J Homan, WHG Lewin, P Kretschmar, A Domingo, JM Mas-Hesse, R Wijnands, AC Fabian, RP Fender, M van der Klis

Measuring the accretion rate and kinetic luminosity functions of supermassive black holes

(2007)

Authors:

EG Koerding, S Jester, R Fender

The first polarimetric signatures of infrared jets in X-ray binaries

(2007)

Authors:

T Shahbaz, RP Fender, CA Watson, K O'Brien

Low accretion rates at the AGN cosmic downsizing epoch

ArXiv 0709.0786 (2007)

Authors:

A Babic, L Miller, MJ Jarvis, TJ Turner, DM Alexander, SM Croom

Abstract:

Context: X-ray surveys of Active Galactic Nuclei (AGN) indicate `cosmic downsizing', with the comoving number density of high-luminosity objects peaking at higher redshifts (z about 2) than low-luminosity AGN (z<1). Aims: We test whether downsizing is caused by activity shifting towards low-mass black holes accreting at near-Eddington rates, or by a change in the average rate of accretion onto supermassive black holes. We estimate the black hole masses and Eddington ratios of an X-ray selected sample of AGN in the Chandra Deep Field South at z<1, probing the epoch where AGN cosmic downsizing has been reported. Methods: Black hole masses are estimated both from host galaxy stellar masses, which are estimated from fitting to published optical and near-infrared photometry, and from near-infrared luminosities, applying established correlations between black hole mass and host galaxy properties. Both methods give consistent results. Comparison and calibration of possible redshift-dependent effects is also made using published faint host galaxy velocity dispersion measurements. Results: The Eddington ratios in our sample span the range 10^{-5} to 1, with median log(L_bol/L_Edd)=-2.87, and with typical black hole masses about 10^{8} solar masses. The broad distribution of Eddington ratios is consistent with that expected for AGN samples at low and moderate luminosity. We find no evidence that the CDF-S AGN population is dominated by low-mass black holes accreting at near-Eddington ratios and the results suggest that diminishing accretion rates onto average-sized black holes are responsible for the reported AGN downsizing at redshifts below unity.