A nearby
star, visible with the unaided eye, is ringed with two rocky asteroid belts and
an outer icy halo, making it a three-ring cosmic circus. The inner asteroid
belt appears to be a virtual twin to the belt in our solar system.
The
presence of the separate rings of material around the nearby star, called Epsilon
Eridani, suggests unseen planets lurk there, where they confine and shape the
rings, say the researchers.
If there
were in fact rocky planets within the inner gap between the star and asteroid belt, the worlds
would likely reside within the star's habitable
zone where temperatures would be such that life could survive.
Located 10.5
light-years from Earth in the constellation Eridanus, the star is the ninth
closest to the sun. The sun's three nearest
known stars are gravitationally bound in a system called Alpha Centauri
that's located 4.36 light-years away. (A light-year is the distance light
travels in one year, or about 6 trillion miles, or 10 trillion km.)
Epsilon
Eridani is slightly smaller and cooler than the sun. And it's also younger.
While the sun is an estimated 4.5 billion years old, Epsilon Eridani has been
around for just 850 million years.
"Studying
Epsilon Eridani is like having a time machine to look at our solar system when it was
young," said researcher Massimo Marengo, an astronomer at the Harvard-Smithsonian Center for Astrophysics in Massachusetts.
Rocky
rings
Astronomers
had known about the star's outer icy ring, but they were surprised when NASA's
Spitzer Space Telescope revealed two rocky rings between the icy halo and the star.
The inner
asteroid belt looks identical to ours in terms of material, and it orbits at 3
astronomical units (AU) from Epsilon Eridani — the same distance between the
sun and the rocky asteroid belt between Mars and Jupiter. (An astronomical unit
equals the average Earth-sun distance of 93 million miles, or about 150 million
km.)
Epsilon
Eridani's second asteroid belt is 20 AU from the star, or about where Uranus is
in relation to our sun, and it is crowded with as much mass as Earth's moon.
The outer
icy ring, previously observed, extends about 35 AU to 100 AU from Epsilon
Eridani and is similar in composition to our Kuiper Belt, a region of icy
objects beyond Neptune. Eridani's outer ring holds about 100 times more
material than ours, however.
New
exoplanets?
The rings
formed when the system was very young, likely when collisions between planets
and other smaller bodies resulted in small bits and big chunks of debris that
took shape as the asteroid belts and icy ring, the researchers suggest.
And the gaps
between these rings were likely shaped by planets whose gravitational forces
could remove any excess material flung from the belts, while also keeping the
shape of the rings. Planets in our solar system exert similar shaping effects.
"The
big planets that are now keeping those gaps are determining the geometry of the
system of rings," Marengo told SPACE.com.
He and his
colleagues propose three planets with masses between those of Neptune and
Jupiter could be in orbit about Epsilon Eridani. A Jupiter-mass
exoplanet was detected in 2000 by the radial velocity method in which
astronomers look for wobbling motion of a star due to the gravitational tug of
a planet. That planet is located near the edge of the innermost ring.
A second
planet must lurk near the second asteroid belt, and a third at about 35 AU near
the inner edge of Epsilon Eridani's Kuiper Belt, the researchers say. Terrestrial
planets could reside inside the innermost asteroid belt as well, though there
currently is no clear indication of that, Marengo said.
The research will be detailed in the Jan. 10 issue of The Astrophysical Journal.
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