The Nirspec Ultracool Dwarf Radial Velocity Survey
Blake, Cullen H.
White, Russel J.
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CitationBlake, Cullen H., David Charbonneau, and Russel J. White. 2010. “THE NIRSPEC ULTRACOOL DWARF RADIAL VELOCITY SURVEY.” The Astrophysical Journal 723 (1): 684–706. https://doi.org/10.1088/0004-637x/723/1/684.
AbstractWe report the results of an infrared Doppler survey designed to detect brown dwarf and giant planetary companions to a magnitude-limited sample of ultracool dwarfs. Using the NIRSPEC spectrograph on the Keck II telescope, we obtained approximately 600 radial velocity (RV) measurements over a period of six years of a sample of 59 late-M and L dwarfs spanning spectral types M8/L0 to L6. A subsample of 46 of our targets has been observed on three or more epochs. We rely on telluric CH4 absorption features in Earth's atmosphere as a simultaneous wavelength reference and exploit the rich set of CO absorption features found in the K-band spectra of cool stars and brown dwarfs to measure RVs and projected rotational velocities. For a bright, slowly rotating M dwarf standard we demonstrate an RV precision of 50 m s(-1) and for slowly rotating L dwarfs we achieve a typical RV precision of approximately 200 m s(-1). This precision is sufficient for the detection of close-in giant planetary companions to mid-L dwarfs as well as more equal mass spectroscopic binary systems with small separations (a < 2 AU). We present an orbital solution for the subdwarf binary LSR1610-0040 as well as an improved solution for the M/T binary 2M0320-04. We compare the distribution of our observed values for the projected rotational velocities, V sin i, to those in the literature and find that our sample contains examples of slowly rotating mid-L dwarfs, which have not been seen in other surveys. We also combine our RV measurements with distance estimates and proper motions from the literature and estimate the dispersion of the space velocities of the objects in our sample. Using a kinematic age estimate, we conclude that our UCDs have an age of 5.0(-0.6)(+0.7) Gyr, similar to that of nearby sun-like stars. We simulate the efficiency with which we detect spectroscopic binaries and find that the rate of tight (a < 1 AU) binaries in our sample is 2.5(-1.6)(+8.6)%, consistent with recent estimates in the literature of a tight binary fraction of 3%-4%.
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