Beecroft Institute for Particle Astrophysics and Cosmology

The 21-cm radiation from minihaloes as a probe of small primordial non-Gaussianity

MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY 426:1 (2012) L21-L25

Authors:

Sirichai Chongchitnan, Joseph Silk

The current status of galaxy formation

RESEARCH IN ASTRONOMY AND ASTROPHYSICS 12:8 (2012) 917-946

Authors:

Joseph Silk, Gary A Mamon

The impact of high spatial frequency atmospheric distortions on weak-lensing measurements

MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY 421:1 (2012) 381-389

Authors:

Catherine Heymans, Barnaby Rowe, Henk Hoekstra, Lance Miller, Thomas Erben, Thomas Kitching, Ludovic Van Waerbeke

Triggered star formation in the inner filament of Centaurus A

Monthly Notices of the Royal Astronomical Society (2012)

Authors:

RM Crockett, SS Shabala, S Kaviraj, V Antonuccio-Delogu, J Silk, M Mutchler, RW O'Connell, M Rejkuba, BC Whitmore, RA Windhorst

Feeding compact bulges and supermassive black holes with low angular-momentum cosmic gas at high redshift

ArXiv 1112.2479 (2011)

Authors:

Yohan Dubois, Christophe Pichon, Martin Haehnelt, Taysun Kimm, Adrianne Slyz, Julien Devriendt, Dmitry Pogosyan

Abstract:

We use cosmological hydrodynamical simulations to show that a significant fraction of the gas in high redshift rare massive halos falls nearly radially to their very centre on extremely short timescales. This process results in the formation of very compact bulges with specific angular momentum a factor 5-30$smaller than the average angular momentum of the baryons in the whole halo. Such low angular momentum originates both from segregation and effective cancellation when the gas flows to the centre of the halo along well defined cold filamentary streams. These filaments penetrate deep inside the halo and connect to the bulge from multiple rapidly changing directions. Structures falling in along the filaments (satellite galaxies) or formed by gravitational instabilities triggered by the inflow (star clusters) further reduce the angular momentum of the gas in the bulge. Finally, the fraction of gas radially falling to the centre appears to increase with the mass of the halo; we argue that this is most likely due to an enhanced cancellation of angular momentum in rarer halos which are fed by more isotropically distributed cold streams. Such an increasingly efficient funnelling of low-angular momentum gas to the centre of very massive halos at high redshift may account for the rapid pace at which the most massive supermassive black holes grow to reach observed masses around $10^9$M$_\odot$ at an epoch when the Universe is barely 1 Gyr old.