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A New Brown Dwarf Desert? A Scarcity of Wide Ultracool Binaries

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 Added by Peter Allen
 Publication date 2006
  fields Physics
and research's language is English




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We present the results of a deep-imaging search for wide companions to low-mass stars and brown dwarfs using NSFCam on IRTF. We searched a sample of 132 M7-L8 dwarfs to magnitude limits of $J sim 20.5$ and $K sim 18.5$, corresponding to secondary-primary mass ratios of $sim 0.5$. No companions were found with separations between $2{arcsec}$ to $31{arcsec}$ ($sim$40 AU to $sim$1000 AU). This null result implies a wide companion frequency below 2.3% at the 95% confidence level within the sensitivity limits of the survey. Preliminary modeling efforts indicate that we could have detected 85% of companions more massive than $0.05 M_{odot}$ and 50% above $0.03 M_{odot}$.



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88 - John E. Gizis 2001
We use three field L and T dwarfs which were discovered to be wide companions to known stars by the Two Micron All-Sky Survey (2MASS) to derive a preliminary brown dwarf companion frequency. Observed L and T dwarfs indicate that brown dwarfs are not unusually rare as wide (Delta >1000 A.U.) systems to F-M0 main-sequence stars (M>0.5M_sun, M_V<9.5), even though they are rare at close separation (Delta <3 A.U.), the ``brown dwarf desert. Stellar companions in these separation ranges are equally frequent, but brown dwarfs are >~ 10 times as frequent for wide than close separations. A brown dwarf wide-companion frequency as low as the 0.5% seen in the brown dwarf desert is ruled out by currently-available observations.
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