期刊
ASTROPHYSICAL JOURNAL
卷 781, 期 1, 页码 -出版社
IOP PUBLISHING LTD
DOI: 10.1088/0004-637X/781/1/28
关键词
methods: observational; planets and satellites: detection; planets and satellites: fundamental parameters; techniques: high angular resolution; techniques: radial velocities
资金
- W.M. Keck Foundation
- National Aeronautics and Space Administration
- National Science Foundation
- National Science Foundation [DGE1144469]
- NASA [NNX13AB03G]
- David and Lucile Packard Foundation
- Alfred P. Sloan Foundation
- NASA [476515, NNX13AB03G] Funding Source: Federal RePORTER
Doppler-based planet surveys have discovered numerous giant planets but are incomplete beyond several AU. At larger star-planet separations, direct planet detection through high-contrast imaging has proven successful, but this technique is sensitive only to young planets and characterization relies upon theoretical evolution models. Here we demonstrate that radial velocity measurements and high-contrast imaging can be combined to overcome these issues. The presence of widely separated companions can be deduced by identifying an acceleration (long-term trend) in the radial velocity of a star. By obtaining high spatial resolution follow-up imaging observations, we rule out scenarios in which such accelerations are caused by stellar binary companions with high statistical confidence. We report results from an analysis of Doppler measurements of a sample of 111 M-dwarf stars with a median of 29 radial velocity observations over a median time baseline of 11.8 yr. By targeting stars that exhibit a radial velocity acceleration (trend) with adaptive optics imaging, we determine that 6.5% +/- 3.0% of M-dwarf stars host one or more massive companions with 1 < m/M-J < 13 and 0 < a < 20 AU. These results are lower than analyses of the planet occurrence rate around higher-mass stars. We find the giant planet occurrence rate is described by a double power law in stellar mass M and metallicity F = [Fe/H] such that f(M, F) = 0.039(-0.028)(+0.056)M(0.8+1.1-0.9)10((3.8 +/- 1.2)F). Our results are consistent with gravitational microlensing measurements of the planet occurrence rate; this study represents the first model-independent comparison with microlensing observations.
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