NASA Scientist Finds World With Triple Sunsets
A NASA-funded astronomer has discovered a world where the sun
sets over the horizon, followed by a second sun and then a third.
The new planet, called HD 188753 Ab, is the first known to reside
in a classic triple-star system.
Image right: This artist's animation shows the view from a hypothetical moon in orbit around the first known planet to reside in a tight-knit triple-star system. The gas giant planet, discovered using the Keck I telescope atop Mauna Kea in Hawaii, zips around a single star that is orbited by a nearby pair of pirouetting stars. Image/animation credit: NASA/JPL-Caltech.
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"The sky view from this planet would be spectacular, with an
occasional triple sunset," said Dr. Maciej Konacki (MATCH-ee Konn-ATZ-kee)
of the California Institute of Technology, Pasadena, Calif.,
who found the planet using the Keck I telescope atop Mauna Kea
mountain in Hawaii. "Before now, we had no clues about whether
planets could form in such gravitationally complex systems."
The finding, reported in this week's issue of Nature, suggests that
planets are more robust than previously believed.
"This is good news for planets," said Dr. Shri Kulkarni, who oversees
Konacki's research at Caltech. "Planets may live in all sorts of
interesting neighborhoods that, until now, have gone largely unexplored."
Kulkarni is the interdisciplinary scientist for NASA's planned SIM PlanetQuest
mission, which will search for signs of Earth-like worlds.
Image left: This artist's concept shows the orbits of a triple-star system called HD 188753, which was discovered to harbor a gas giant, or "hot Jupiter," planet. Image/animation credit: NASA/JPL-Caltech.
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+ Quicktime showing orbit paths of system with three suns
Systems with multiple stars are widespread throughout the universe,
accounting for more than half of all stars. Our Sun's closest star,
Alpha Centauri, is a member of a trio.
"Multiple-star systems have not been popular planet-hunting grounds,"
said Konacki. "They are difficult to observe and were believed to be
inhospitable to planets."
The new planet belongs to a common class of extrasolar planets called
"hot Jupiters," which are gas giants that zip closely around their
parent stars. In this case, the planet whips every 3.3 days around a star
that is circled every 25.7 years by a pirouetting pair of stars locked
in a 156-day orbit.
The circus-like trio of stars is a cramped bunch, fitting into the same
amount of space as the distance between Saturn and our Sun. Such tight
living quarters throw theories of hot Jupiter formation into question.
Astronomers had thought that hot Jupiters formed far away from their
parent stars, before migrating inward.
"In this close-knit system, there would be no room at the outskirts of
the parent star system for a planet to grow," said Konacki.
Previously, astronomers had identified planets around about 20 binary
stars and one set of triple stars. But the stars in those systems had a
lot of space between them. Most multiple-star arrangements are crowded
together and difficult to study.
Konacki overcame this challenge using a modified version of the radial
velocity, or "wobble," planet-hunting technique. In the traditional
wobble method, a planet's presence is inferred by the gravitational tug,
or wobble, it induces in its parent star. The strategy works well for
single stars or far-apart binary and triple stars, but could not be
applied to close-star systems because the stars' light blends together.
By developing detailed models of close-star systems, Konacki was able
to tease apart the tangled starlight. This allowed him to pinpoint,
for the first time, the tug of a planet on a star snuggled next to
other stars. Of 20 systems examined so far, HD 188753, located 149
light-years away, was the only one found to harbor a planet.
Hot Jupiters are believed to form out of thick disks, or "doughnuts,"
of material that swirl around the outer fringes of young stars. The disk
material clumps together to form a solid core, then pulls gas onto it.
Eventually, the gas giant drifts inward. The discovery of a world under
three suns contradicts this scenario. HD 188753 would have sported a
truncated disk in its youth, due to the disruptive presence of its
stellar companions. That leaves no room for HD 188753's planet to form,
and raises a host of new questions.
The masses of the three stars in HD 188753 system range from two-thirds
to about the same mass as our Sun. The planet is slightly more massive
For artist's concepts and other graphics, visit http://planetquest.jpl.nasa.gov/
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Whitney Clavin (818) 354-4673
Jet Propulsion Laboratory, Pasadena, Calif.