UW: Far-off Worlds 'Characterization by Proxy'

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UW: Far-off Worlds 'Characterization by Proxy'

Post by bystander » Fri Apr 26, 2013 11:36 pm

Far-off Worlds Studied Through 'Characterization by Proxy'
University of Washington | 2013 Apr 25

A University of Washington astronomer is using Earth’s interstellar neighbors to learn the nature of certain stars too far away to be directly measured or observed, and the planets they may host.

“Characterization by proxy” is the technique used by Sarah Ballard, a post-doctoral researcher at the UW, to infer the properties of small, relatively cool stars too distant for measurement, by comparing them to closer stars that now can be directly observed.

Ballard is lead author of a study accepted for publication in The Astrophysical Journal that used this method and observations from the Kepler Space Telescope to learn the nature of the distant star Kepler-61.

Our understanding of the size and temperature of planets depends crucially on the size and temperature of the stars they orbit. Astronomers already have a robust way to discern the physical properties of solar-type stars — those like the sun — by measuring the light they emit at different wavelengths and matching that to synthetically created spectra.

“The challenge is that small stars are incredibly difficult to characterize,” Ballard said. Those theoretical methods don’t work well for what are called M-dwarf stars, lower-mass stars about half the size of the sun and smaller — which is too bad, because such stars make up about three-quarters of the universe.

Ballard is using the characterization by proxy method to try to fill this knowledge gap. She is building on what she calls “truly remarkable” work by astronomer Tabetha Boyajian, now at Yale University, who uses a near-infrared interferometer — an array of telescopes working in unison studying light wavelengths a bit longer than visible light — to resolve the physical size of relatively nearby stars.

Ballard said her characterization by proxy method takes “full advantage that there now exists this precious sample” of relatively nearby stars that have been directly measured. You could say the method borrows a bit from Greek mathematician Euclid, whose first “common notion” held that things that equal the same thing must necessarily also equal each other.

In the new paper, Ballard and co-authors used this reasoning to learn about Kepler-61b, a planet orbiting near the inner edge of the habitable zone of the distant, low-mass star Kepler-61, about 900 light-years away in the Cygnus Constellation. A star’s habitable zone is that swath of space just right for an orbiting planet’s surface water to be in liquid form, thus giving life a chance.

She did this by comparing it to temperature size averages from four spectroscopically similar stars between 12 and 25 light-years away in the Ursa Major and Cygnus constellations. A light-year is about 6 trillion miles.

A funny thing also happened along the way: Kepler-61 turned out to be bigger and hotter than expected, which in turn recalibrated planet Kepler-61b’s relative size upward as well — meaning it, too, would be hotter than previously thought and no longer a resident of the star’s habitable zone.

All of this caused Ballard to informally subtitle the paper, “How Nearby Stars Bumped a Planet out of the Habitable Zone”.

Exoplanet Characterization by Proxy: a Transiting 2.15 R_Earth Planet Near the Habitable Zone of the Late K dwarf Kepler-61 - Sarah Ballard et al
How Do You Measure A Planet Near A Tiny Star?
Universe Today | Elizabeth Howell | 2013 Apr 26
Know the quiet place within your heart and touch the rainbow of possibility; be
alive to the gentle breeze of communication, and please stop being such a jerk.
— Garrison Keillor

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SAO: Studying a Super-Earth Located Near its Habitable Zone

Post by bystander » Sun Sep 01, 2013 7:00 pm

Studying a Super-Earth Located Near its Habitable Zone
Smithsonian Astrophysical Observatory
Weekly Science Update | 2013 Aug 09
Astronomers are steadily zeroing in on Earth-like exoplanets: those transiting terrestrial-sized exoplanets located in their stellar habitable zones (the region where temperatures allow water to remain liquid) around Sun-like stars or more abundant, lower-mass stars. The first one discovered, by NASA's Kepler mission, was Kepler-22b, but its radius of 2.4 Earth-radii was a bit too large to facilitate an Earth-like composition. Other candidates, in the Kepler-20, Kepler-42, and Kepler-68 systems, orbit too close to their host stars to lie within the habitable zone. On the other hand, the star Kepler-62 hosts five planets, two of which are very likely to be solid and to reside in their star’s habitable zone; other candidates have been announced as well.

The problem is that the determination of an exoplanet's radius and equilibrium temperature hinges critically on the properties of the star it orbits, and measuring the properties of low-mass stars (like the ones mentioned above) is difficult and problematic. The direct comparison of stellar theory and observation, which is robust for deducing the properties of solar-type stars, is challenging for low-mass stars. The theory relies on detailed, computationally intensive modeling low-mass stellar interiors, and that includes knowing the complex array of molecules and grains that reside in the stellar atmospheres. For this reason, astronomers often appeal to empirical, rather than theoretical, methods for the physical characterization of low-mass stars -- but this is fraught with other possible assumptions such as about stellar activity or element abundances.

CfA astronomers Sarah Ballard, David Charbonneau, Francois Fressing, Guillermo Torres, Jonathan Irwin, and Elisabeth Newton, along with their colleagues, have come up with a promising alternative. In order to model the properties of the exoplanet around the low-mass star Kepler 61, they examine a set of other nearby low-mass stars. Using additional ground-based observations of the set, they compare the properties to derive the most-likely properties of Kepler 61, finding that it has a size of 0.62 solar-radii and a surface temperature of 4000 kelvin. They then model the transiting exoplanet to have a radius of 2.15 Earth-radii and an equilibrium temperature of 273 +-13 kelvin. They conclude that the exoplanet is probably too large to be terrestrial in composition, but has a moderate temperature and is likely to contain an atmosphere. Although the Kepler satellite has ceased regular operations, the dataset it has acquired is expected to continue to provide new results, and this new technique offers a way to obtain more reliable values for planetary parameters.

Exoplanet Characterization by Proxy: A Transiting 2.15 R Planet near the Habitable Zone of the Late K Dwarf Kepler-61 - Sarah Ballard et al
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Know the quiet place within your heart and touch the rainbow of possibility; be
alive to the gentle breeze of communication, and please stop being such a jerk.
— Garrison Keillor

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