Astronomical instrumentation

The Oxford-Dartmouth Thirty Degree Survey II: Clustering of Bright Lyman Break Galaxies: strong luminosity dependent bias at redshift 4

Monthly Notices of the Royal Astronomical Society 360 (2005) 1244-1256

Authors:

GB Dalton, P.D. Allen, L.A. Moustakas, E.C. MacDonald

The discovery of a galaxy-wide superwind from a young massive galaxy at redshift z ~ 3

Nature 436 (2005) 227-229

Authors:

RJ Wilman, J. Gerssen, R.G. Bower, S.L. Morris

Hyperfine splitting of [Al VI] 3.66 μm and the Al isotopic ratio in NGC 6302

Monthly Notices of the Royal Astronomical Society 359:4 (2005) 1386-1392

Authors:

S Casassus, PJ Storey, MJ Barlow, PF Roche

Abstract:

The core of planetary nebula NGC 6302 is filled with high-excitation photoionized gas at low expansion velocities. It represents a unique astrophysical situation in which to search for hyperfine structure (HFS) in coronal emission lines from highly ionized species. HFS is otherwise blended by thermal or velocity broadening. Spectra containing [Al VI] 3.66 μm 3P2 ← 3P1, obtained with Phoenix on Gemini South at resolving powers of up to 75000, resolve the line into five hyperfine components separated by 20-60 km s-1 as a result of the coupling of the I = 5/2 nuclear spin of 27Al with the total electronic angular momentum J. The isotope 26Al has a different nuclear spin of I = 5, and a different HFS, which allows us to place a 3σ upper limit on the 26Al/27 AI abundance ratio of 1/33. We measure the HFS magnetic dipole coupling constants for [Al VI], and provide the first estimates of the electric quadrupole HFS coupling constants obtained through astronomical observations of an atomic transition. © 2005 RAS.

Source subtraction for the extended Very Small Array and 33-GHz source count estimates

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 360:1 (2005) 340-353

Authors:

Kieran A Cleary, Angela C Taylor, Elizabeth Waldram, Richard A Battye, Clive Dickinson, Rod D Davies, Richard J Davis, Ricardo Genova-Santos, Keith Grainge, Michael E Jones, Rüdiger Kneissl, GG Pooley, Rafael Rebolo, José Alberto Rubiño-Martín, Richard DE Saunders, Paul F Scott, Anže Slosar, David Titterington, Robert A Watson

Star-formation in NGC 4038/4039 from broad- and narrow band photometry: Cluster Destruction?

ArXiv astro-ph/0505445 (2005)

Authors:

Sabine Mengel, Matthew D Lehnert, Niranjan Thatte, Reinhard Genzel

Abstract:

Accurately determining the star formation history in NGC 4038/4039 -- ``The Antennae'' is hampered by extinction. We therefore used near infrared images obtained with ISAAC at the VLT and with SOFI at the NTT to determine the recent star formation history in this merger. In combination with archival HST data, we determined ages, extinction and other parameters for single star clusters, and properties of the cluster population as a whole. About 70% of the K_s-band detected star clusters with masses >= 10^5 M_sun are younger than 10 Myrs (approximately an e-folding time for cluster ages), which we interpret as evidence for rapid dissolution but not free expansion. The total mass of K-band selected clusters is about 5-10x10^8 M_sun and represents about 3-6% of the total molecular gas. This takes into account only the detected clusters and in view of the rapid dissolution means that this is only a lower limit to the total mass of stars produced in clusters during the burst. Studies of cluster formation in other galaxies recently suggested short cluster dissolution timescales, too, which means that star formation rates may have been severely underestimated in the past. Extinction is strongly variable and very high in some regions, but around A_V=1.3 mag on average. Even though most clusters are detected at least in I-band, only the information about individual cluster ages and extinction allows to avoid uncertainties of orders of magnitude in star formation rate estimates determined from optical fluxes. From the distribution of individual cluster extinction vs. age, which is significantly higher for clusters below 8-9 Myr than for older clusters, we infer that this is the time by which a typical cluster blows free of its native dust cocoon.