Cosmology

Herschel-ATLAS: The angular correlation function of submillimetre galaxies at high and low redshift

Astronomy and Astrophysics 518:3 (2010)

Authors:

SJ Maddox, L Dunne, E Rigby, S Eales, A Cooray, D Scott, JA Peacock, M Negrello, DJB Smith, D Benford, A Amblard, R Auld, M Baes, D Bonfield, D Burgarella, S Buttiglione, A Cava, D Clements, A Dariush, G De Zotti, S Dye, D Frayer, J Fritz, J Gonzalez-Nuevo, D Herranz, E Ibar, R Ivison, MJ Jarvis, G Lagache, L Leeuw, M Lopez-Caniego, E Pascale, M Pohlen, G Rodighiero, S Samui, S Serjeant, P Temi, M Thompson, A Verma

Abstract:

We present measurements of the angular correlation function of galaxies selected from the first field of the H-ATLAS survey. Careful removal of the background from galactic cirrus is essential, and currently dominates the uncertainty in our measurements. For our 250 μm-selected sample we detect no significant clustering, consistent with the expectation that the 250 μm-selected sources are mostly normal galaxies at z < 1. For our 350 μm and 500 μm-selected samples we detect relatively strong clustering with correlation amplitudes A of 0.2 and 1.2 at 1', but with relatively large uncertainties. For samples which preferentially select high redshift galaxies at z∼2-3 we detect significant strong clustering, leading to an estimate of r0 ∼ 7-11 h-1 Mpc. The slope of our clustering measurements is very steep, δ ∼ 2. The measurements are consistent with the idea that sub-mm sources consist of a low redshift population of normal galaxies and a high redshift population of highly clustered star-bursting galaxies. © ESO, 2010.

Weighing black holes using open-loop focus corrections for LGS-AO observations of galaxy nuclei at Gemini Observatory

Proceedings of SPIE--the International Society for Optical Engineering SPIE, the international society for optics and photonics 7736 (2010) 77365w-77365w-8

Authors:

Richard M McDermid, Davor Krajnovic, Michele Cappellari, Chadwick Trujillo, Julian Christou, Roger L Davies

An excess of star-forming galaxies in the fields of high-redshift QSOs

\mnras 405 (2010) 2623-2638-2623-2638

Authors:

JA Stevens, MJ Jarvis, KEK Coppin, MJ Page, TR Greve, FJ Carrera, RJ Ivison

The C-Band All-Sky Survey: instrument design, status, and first-look data

Society of Photo-Optical Instrumentation Engineers (SPIE) Conference Series 7741 (2010)

Authors:

OG King, C Copley, R Davies, R Davis, C Dickinson, YA Hafez, C Holler, JJ John, JL Jonas, ME Jones, JP Leahy, SJC Muchovej, TJ Pearson, ACS Readhead, MA Stevenson, AC Taylor

IR-correlated 31 GHz radio emission from Orion East

Monthly Notices of the Royal Astronomical Society Oxford University Press 407:4 (2010) 2223-2229

Authors:

C Dickinson, S Casassus, RD Davies, JR Allison, R Bustos, K Cleary, RJ Davis, Michael Jones, TJ Pearson, ACS Readhead, R Reeves, Angela Taylor, CT Tibbs, RA Watson

Abstract:

Lynds dark cloud LDN1622 represents one of the best examples of anomalous dust emission, possibly originating from small spinning dust grains. We present Cosmic Background Imager (CBI) 31-GHz data of LDN1621, a diffuse dark cloud to the north of LDN1622 in a region known as Orion East. A broken ring-like structure with diameter ≈20 arcmin of diffuse emission is detected at 31 GHz, at ≈20–30 mJy beam−1 with an angular resolution of ≈5 arcmin. The ring-like structure is highly correlated with far-infrared (FIR) emission at 12–100 μm with correlation coefficients of r≈ 0.7–0.8, significant at ∼10σ. The FIR-correlated emission at 31 GHz therefore appears to be mostly due to radiation associated with dust. Multifrequency data are used to place constraints on other components of emission that could be contributing to the 31-GHz flux. An analysis of the GB6 survey maps at 4.85 GHz yields a 3σ upper limit on free–free emission of 7.2 mJy beam−1 (≲30 per cent of the observed flux) at the CBI resolution. The bulk of the 31-GHz flux therefore appears to be mostly due to dust radiation. Aperture photometry, at an angular resolution of 13 arcmin and with an aperture of diameter 30 arcmin, allowed the use of IRAS maps and the Wilkinson Microwave Anisotropy Probe 5-yr W-band map at 93.5 GHz. A single modified blackbody model was fitted to the data to estimate the contribution from thermal dust, which amounts to ∼10 per cent at 31 GHz. In this model, an excess of 1.52 ± 0.66 Jy (2.3σ) is seen at 31 GHz. Correlations with the IRAS 100 μm gave a coupling coefficient of 18.1 ± 4.4 μK (MJy sr−1)−1, consistent with the values found for LDN1622.