The discovery of the unusual supernova SN1998bw, and its possible association with the ␥-ray burst GRB 980425 1-3 , provide new insights into the explosion mechanism of very massive stars and the origin of some classes of ␥-ray bursts. Optical spectra indicate that SN1998bw is a type Ic supernova 3,4 , but its peak luminosity is unusually high compared with typical type Ic supernovae 3 . Here we report our findings that the optical spectra
We present a catalog of nearby exoplanets, available at http://exoplanets.org and ApJ 646, 505 (published version available at the link above). It contains the 172 known low mass companions with orbits established through radial velocity and transit measurements around stars within 200 pc. We include 5 previously unpublished exoplanets orbiting the stars HD 11964, HD 66428, HD 99109, HD 107148, and HD 164922. We update orbits for 90 additional exoplanets including many whose orbits have not been revised since their announcement, and include radial velocity time series from the Lick, Keck, and Anglo-Australian Observatory planet searches. Both these new and previously published velocities are more precise here due to improvements in our data reduction pipeline, which we applied to archival spectra. We present a brief summary of the global properties of the known exoplanets, including their distributions of orbital semimajor axis, minimum mass, and orbital eccentricity.Comment: 45-page preprint version. The published ApJ version is available at http://adsabs.harvard.edu/cgi-bin/nph-bib_query?bibcode=2006ApJ...646..505B . Find further information at http://exoplanets.or
We present the discovery of another seven Y dwarfs from the Wide-field Infrared Survey Explorer (WISE). Using these objects, as well as the first six WISE Y dwarf discoveries from Cushing et al., we further explore the transition between spectral types T and Y. We find that the T/Y boundary roughly coincides with the spot where the J − H colors of brown dwarfs, as predicted by models, turn back to the red. Moreover, we use preliminary trigonometric parallax measurements to show that the T/Y boundary may also correspond to the point at which the absolute H (1.6 µm) and W2 (4.6 µm) magnitudes plummet. We use these discoveries and their preliminary distances to place them in the larger context of the Solar Neighborhood. We present a table that updates the entire stellar and substellar constinuency within 8 parsecs of the Sun, and we show that the current census has hydrogen-burning stars outnumbering brown dwarfs by roughly a factor of six. This factor will decrease with time as more brown dwarfs are identified within this volume, but unless there is a vast reservoir of cold brown dwarfs -2invisible to WISE, the final space density of brown dwarfs is still expected to fall well below that of stars. We also use these new Y dwarf discoveries, along with newly discovered T dwarfs from WISE, to investigate the field substellar mass function. We find that the overall space density of late-T and early-Y dwarfs matches that from simulations describing the mass function as a power law with slope −0.5 < α < 0.0; however, a power-law may provide a poor fit to the observed object counts as a function of spectral type because there are tantalizing hints that the number of brown dwarfs continues to rise from late-T to early-Y. More detailed monitoring and characterization of these Y dwarfs, along with dedicated searches aimed at identifying more examples, are certainly required.2 Our team also maintains ancillary lists of candidates with bluer colors or fainter magnitudes, but those are beyond the scope of this paper. AAT/IRIS2The IRIS2 instrument (Tinney et al. 2004) at the 3.9m Anglo-Australian Telescope (AAT) at Siding Spring Observatory, Australia, provides wide-field imaging (7. ′ 7×7. ′ 7) using a 1024×1024 (0. ′′ 4486 pixel −1 ) Rockwell HAWAII-1 HgCdTe infrared detector. Our observation of WISE 2220−3628 used only the J filter, which is on the MKO-NIR system (Tokunaga et al. 2002). Data collection and reduction for this instrument are described in Tinney et al. (in prep.). CTIO/NEWFIRMThe NOAO Extremely Wide Field Infrared Imager (NEWFIRM; Swaters et al. 2009) at the 4m Victor M. Blanco Telescope on Cerro Tololo, Chile, uses four 2048×2048 InSb arrays arranged in a 2×2 grid. With a pixel scale of 0. ′′ 40 pixel −1 , this grid covers a total field of view of 27. ′ 6×27. ′ 6. Only one of our new Y dwarfs, WISE 0734−7157, was acquired with this instrument and it was observed only at J band, which is on the MKO-NIR system. Observing and reduction strategies are described in Kirkpatrick et al. (2011). SOAR/SpartanIRCThe Spart...
We present a kinematic analysis of 152 low surface gravity M7-L8 dwarfs by adding 18 new parallaxes (including 10 for comparative field objects), 38 new radial velocities, and 19 new proper motions. We also add low- or moderate-resolution near-infrared spectra for 43 sources confirming their low surface gravity features. Among the full sample, we find 39 objects to be high-likelihood or new bona fide members of nearby moving groups, 92 objects to be ambiguous members and 21 objects that are non-members. Using this age-calibrated sample, we investigate trends in gravity classification, photometric color, absolute magnitude, color–magnitude, luminosity, and effective temperature. We find that gravity classification and photometric color clearly separate 5–130 Myr sources from >3 Gyr field objects, but they do not correlate one to one with the narrower 5–130 Myr age range. Sources with the same spectral subtype in the same group have systematically redder colors, but they are distributed between 1 and 4σ from the field sequences and the most extreme outlier switches between intermediate- and low-gravity sources either confirmed in a group or not. The absolute magnitudes of low-gravity sources from the J band through W3 show a flux redistribution when compared to equivalently typed field brown dwarfs that is correlated with spectral subtype. Low-gravity, late-type L dwarfs are fainter at J than the field sequence but brighter by W3. Low-gravity M dwarfs are >1 mag brighter than field dwarfs in all bands from J through W3. Clouds, which are a far more dominant opacity source for L dwarfs, are the likely cause. On color–magnitude diagrams, the latest-type, low-gravity L dwarfs drive the elbow of the L/T transition up to 1 mag redder and 1 mag fainter than field dwarfs at M J but are consistent with or brighter than the elbow at M W1 and M W2. We conclude that low-gravity dwarfs carry an extreme version of the cloud conditions of field objects to lower temperatures, which logically extends into the lowest-mass, directly imaged exoplanets. Furthermore, there is an indication on color-magnitude diagrams (CMDs; such as M J versus (J–W2)) of increasingly redder sequences separated by gravity classification, although it is not consistent across all CMD combinations. Examining bolometric luminosities for planets and low-gravity objects, we confirm that (in general) young M dwarfs are overluminous while young L dwarfs are normal compared to the field. Using model extracted radii, this translates into normal to slightly warmer M dwarf temperatures compared to the field sequence and lower temperatures for L dwarfs with no obvious correlation with the assigned moving group.
We review the observed properties of exoplanets found by the Doppler
technique which has revealed 152 exoplanets to date. We focus on our ongoing
18-year survey of 1330 FGKM type stars at Lick, Keck, and the Anglo-Australian
Telescopes carried out with a uniform Doppler precision of 3 m/s. The 104
planets detected in our survey have masses as low as 15 M_Earth orbiting
between 0.03 and 5.5 AU. The mass distribution rises toward the lowest
detectable masses as dN/dM is proportional to M^-1.1. Nearly all giant planets
orbiting within 2 AU of all FGK stars within 30 pc have now been discovered.
The distribution of semi-major axes rises from 0.3 -- 3.0 AU (in bins of Delta
log a), but remains unknown for larger orbits. Extrapolation suggests that 12%
of the FGK stars harbor exoplanets within 20 AU. The median orbital
eccentricity is
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