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rfmcdonaldScience Daily's report on the discovery of the planetary system of red dwarf KOI-961 explores how that star's similarities to Barnard's Star--a nearby red dwarf, second-closest star to our solar system after the three of Alpha Centauri, itself believed to host planets by earlier generations of planet-hunters--helped astronomers build a model for KOI-961's system.
Sol Station's profile of Barnard's Star, linked above, suggests that a habitable world orbiting that star would need to have an orbit of roughly one to three weeks.
The team used data from NASA's Kepler mission combined with additional observations of a single star, called KOI-961, to determine that it possesses three planets that range in size from 0.57 to 0.78 times the radius of Earth. This makes them the smallest of the more than 700 exoplanets confirmed to orbit other stars.
In their investigation of KOI-961, which is about 130 light years away in the Cygnus constellation, the astronomers found that it is nearly identical to Barnard's star, which is only six light years away in the constellation Ophiuchus. This similarity allowed them to use information about Barnard's star, which was discovered in 1916 by Vanderbilt astronomer E.E. Barnard, to determine the mass, size and luminosity of the distant star. These values, in turn, were used to determine the size of the three new exoplanets.
"Barnard's star and KOI-961 are both M dwarfs, which are also known as red dwarfs. This is the smallest category of stars. They are popular targets for exoplanet hunters because their small size makes it easier to detect Earth-sized planets," said Keivan Stassun, the professor of astronomy who headed the Vanderbilt contingent. The other Vanderbilt scientists involved were Research Assistant Professors Joshua Pepper and Leslie Hebb.
From the 1960's through the 1980's, astronomers thought that Barnard's star also had a planetary system -- specifically one or two planets larger than Jupiter. If their existence had been verified, it would have been a scientific first, but the evidence was ultimately discredited. Today, advances in telescope technology and image processing allow astronomers to identify stars with exoplanets with considerable confidence.
[. . .]
Once the size of the star was established, the team used the Kepler data to calculate that the three exoplanets range from the size of Mars to slightly more than three-quarters the size of Earth. They also determined that these planets orbit the star with periods ranging from a half day to two days. Such short periods mean that all three orbit so close to their star that they must be too hot for liquid water to exist and life to evolve, the astronomers calculate.
The diminutive dimensions of this planetary system prompted John Johnson, the principal investigator of the research from NASA's Exoplanet Science Institute at Caltech, to comment, "The really amazing thing about this system is that the closest size comparison is to Jupiter and its moons." (KOI-961 is just 70 percent bigger than Jupiter and its exoplanets are comparable in size and have similar orbital periods to the Galilean moons that circle the Jovian planet.)
Sol Station's profile of Barnard's Star, linked above, suggests that a habitable world orbiting that star would need to have an orbit of roughly one to three weeks.
