* Astronomy

Using the Flamingos-I near-infrared imager at Gemini South, a UK/Japanese team of astronomers has imaged an outer region of the Trapezium Cluster near the centre of the Orion Nebula, and identified 396 sources.
Of these, 138 are brown dwarf candidates and 33 of those are candidate planetary mass objects. This could have an impact on our understanding of the initial mass function (IMF) for very low-mass bodies, especially in a hostile star forming environment.


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Colour composite image from near-infrared J, H and K-band images including two of three fields observed in this Gemini South/Flamingos-I survey of the edge of the Trapezium Cluster at the core of the Orion Nebula.
This edge field was selected to avoid saturation of the core region due to the sensitivity/depth of these observations. Indicated on this image are the two bipolar nebulae (�blow-ups� right) discovered with this data. Also indicated (left of centre) is a grouping of six stars that is representative of a tendency for both stars and brown dwarfs to form in small groups of between four to eight sources.

The observations were made in J, H, and K bands during observing runs in 2001 and 2002. Three fields were imaged for one hour each in K and H bands and two hours in J. The depth of these data allowed the identification of a variety of new low-mass objects, and led to comparisons with other independent surveys of adjacent regions, resulting in statistically significant conclusions.
The survey`s results are expected to provide a wealth of targets for future research in this star-forming region due to its depth and resolution.
An ongoing study by the team is a spectroscopic follow-up with Gemini of the planetary mass objects (PMOs) of M less than 13 MJup.
Due to an increase in background contamination at this luminosity, the present study puts the upper limit of 3-13 MJup PMOs at 13% and likely at less than 10% of the cluster population (assuming an age of one million years for cluster members).

In addition to the identification of two new bipolar nebulae with bright central sources in the region, the study also found multiple trails and filaments that appear to be associated with low luminosity point sources. Others have no apparent point-source associations.
Another result of the survey analysis is that binary pairs of brown dwarfs and very low-mass stars (less than 0.1Msun) are less likely than more massive stars to have wide separations (greater than 150 AU) between them and any binary companions. When this is combined with an independent Subaru sample (of a different region in the Trapezium cluster), this relationship is confirmed to a 96% confidence level. Furthermore, a statistically very significant excess was found for both stars and brown dwarf pairs with small separations (6 arc seconds or 2,600 AU), which is consistent with the "ejected stellar embryo" hypothesis for brown dwarf formation.



A deep survey of brown dwarfs in Orion with Gemini
Authors: P.W.Lucas (1), P.F.Roche (2), M.Tamura (3) ((1) University of Hertfordshire, (2) University of Oxford, (3) NAOJ)

We report the results of a deep near infrared (JHK) survey of the outer parts of the Trapezium Cluster with Gemini South/Flamingos. 396 sources were detected in a 26 arcmin^2 area, including 138 brown dwarf candidates, defined as masses greater than 0.075 solar masses for an assumed age of 1 million years.
Only 33 of the brown dwarf candidates are planetary mass candidates (PMCs) with estimated masses in the range 0.003 and 0.012 solar masses. In an extinction limited sample (A(V) less than 5) complete to approximately 0.005 solar masses (5 Mjup) the mass function appears to drop by a factor of 2 at the deuterium burning threshold, i.e. at planetary masses.
After allowing for background contamination it is likely that planetary mass objects at 3-13 Jupiter masses number less than 10% of the cluster population, with an upper limit of 13%. Analysis of the spatial distribution of stars and brown dwarf candidates suggests that brown dwarfs and very low mass stars (less than 0.1 solar masses) are less likely than more massive stars to have wide (greater than150 AU) binary companions.
This result has modest statistical significance (96%) in our data but is supported at 93% confidence by analysis of a completely independent sample taken from the Subaru data of Kaifu et al.(2000).
There is a statistically very significant excess of both stars and brown dwarfs with small separations from each other (6 arcsec or 2600 AU). This appears to be due to the presence of small N subgroups, which are likely to be dynamically unstable in the long term. Hence these results are consistent with the 'ejected stellar embryo' hypothesis for brown dwarf formation.
We also report the discovery of two new bipolar nebulae, which are interpreted as Class I protostars.

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-- Edited by Blobrana at 01:02, 2005-06-21