Pulsars, transients and relativistic astrophysics

A relativistic jet in the radio-quiet quasar PG1407+263

(2003)

Authors:

Katherine Blundell, Tony Beasley, Geoff Bicknell

The under-explored radio-loudness of quasars and the possibility of radio-source--environment interactions

ArXiv astro-ph/0306110 (2003)

Abstract:

I demonstrate that radio observations in the literature to date of optically-selected quasars are largely inadequate to reveal the full extent of their jet-activity. I discuss a recent example of an optically-powerful quasar, which is radio-quiet according to all the standard classifications, which Blundell & Rawlings discovered to have a >100 kpc jet, and show that other than being the first FRI quasar to be identified, there is no reason to presume it is exceptional. I also discuss a possible new probe of accounting for the interactions of radio sources with their environments. This tool could help to avoid over-estimating magnetic fields strengths within cluster gas. I briefly describe recent analyses by Rudnick & Blundell which confront claims in the literature of cluster gas B-fields > 10 micro-G.

The under-explored radio-loudness of quasars and the possibility of radio-source--environment interactions

(2003)

Gemini observations of Wolf-Rayet stars in the Local Group starburst galaxy IC 10*

Astronomy & Astrophysics EDP Sciences 404:2 (2003) 483-493

Authors:

PA Crowther, L Drissen, JB Abbott, P Royer, SJ Smartt

Gap formation by planets in turbulent protostellar disks

Astrophysical Journal 589:1 I (2003) 543-555

Authors:

WF Winters, SA Balbus, JF Hawley

Abstract:

The processes of planet formation and migration depend intimately on the interaction between planetesimals and the gaseous disks in which they form. The formation of gaps in the disk can severely limit the mass of the planet and its migration toward the protostar. We investigate the process of gap formation through magnetohydrodynamic simulations in which internal stress arises self-consistently from turbulence generated by the magnetorotational instability. The simulations investigate three different planetary masses and two disk temperatures to bracket the tidal (thermal) and viscous gap opening conditions. The results are in general qualitative agreement with previous simulations of gap formation but show significant differences. In the presence of MHD turbulence, the gaps produced are shallower and asymmetrically wider than those produced with pure hydrodynamics. The rate of gap formation is also slowed, with accretion occurring across the developing gap. Viscous hydrodynamics does not adequately describe the evolution, however, because planets capable of producing gaps also may be capable of affecting the level of MHD turbulence in different regions of the disk.