By ANDY FLEMING
Look up at the night sky and you'll see stars,
sure. But you're also seeing planets -- billions and billions of them. At
least.
That's the conclusion of a new study by
astronomers at the California Institute of Technology (Caltech) that provides
yet more evidence that planetary systems are the cosmic norm. The team made
their estimate while analysing planets orbiting a star called Kepler-32 --
planets that are representative, they say, of the vast majority in the galaxy
and thus serve as a perfect case study for understanding how most planets form.
"There are at least 100 billion planets in
the galaxy -- just our galaxy," says John Johnson, assistant professor of
planetary astronomy at Caltech and co-author of the study, which was recently
accepted for publication in the Astrophysical Journal. "That's
mind-boggling."
"It's a staggering number, if you think
about it," adds Jonathan Swift, a postdoc at Caltech and lead author of
the paper. "Basically there's one of these planets per star."
The planetary system in question, which was
detected by the Kepler space telescope, contains five planets. The existence of
two of those planets have already been confirmed by other astronomers. The
Caltech team confirmed the remaining three, then analysed the five-planet
system and compared it to other systems found by the Kepler mission.
The planets orbit a star that is an M dwarf -- a
type that accounts for about three-quarters of all stars in the Milky Way. The
five planets, which are similar in size to Earth and orbit close to their star,
are also typical of the class of planets that the telescope has discovered
orbiting other M dwarfs, Swift says. Therefore, the majority of planets in the
galaxy probably have characteristics comparable to those of the five planets.
While this particular system may not be unique,
what does set it apart is its coincidental orientation: the orbits of the
planets lie in a plane that's positioned such that Kepler views the system
edge-on. Due to this rare orientation, each planet blocks Kepler-32's starlight
as it passes between the star and the Kepler telescope.
By analysing changes in the star's brightness,
the astronomers were able to determine the planets' characteristics, such as
their sizes and orbital periods. This orientation therefore provides an
opportunity to study the system in great detail -- and because the planets
represent the vast majority of planets that are thought to populate the galaxy,
the team says, the system also can help astronomers better understand planet
formation in general.
"I usually try not to call things 'Rosetta
stones,' but this is as close to a Rosetta stone as anything I've seen,"
Johnson says. "It's like unlocking a language that we're trying to
understand -- the language of planet formation."
One of the fundamental questions regarding the
origin of planets is how many of them there are. Like the Caltech group, other
teams of astronomers have estimated that there is roughly one planet per star,
but this is the first time researchers have made such an estimate by studying
M-dwarf systems, the most numerous population of planets known.
To do that calculation, the Caltech team
determined the probability that an M-dwarf system would provide Kepler-32's
edge-on orientation. Combining that probability with the number of planetary
systems Kepler is able to detect, the astronomers calculated that there is, on
average, one planet for every one of the approximately 100 billion stars in the
galaxy. But their analysis only considers planets that are in close orbits
around M dwarfs -- not the outer planets of an M-dwarf system, or those
orbiting other kinds of stars. As a result, they say, their estimate is
conservative. In fact, says Swift, a more accurate estimate that includes data
from other analyses could lead to an average of two planets per star.
M-dwarf systems like Kepler-32's are quite
different from our own solar system. For one, M dwarfs are cooler and much
smaller than the Sun. Kepler-32, for example, has half the mass of the Sun and
half its radius. The radii of its five planets range from 0.8 to 2.7 times that
of Earth, and those planets orbit extremely close to their star. The whole
system fits within just over a tenth of an astronomical unit (the average
distance between Earth and the Sun) -- a distance that is about a third of the
radius of Mercury's orbit around the Sun. The fact that M-dwarf systems vastly
outnumber other kinds of systems carries a profound implication, according to
Johnson, which is that our solar system is extremely rare. "It's just a
weirdo," he says.
The fact that the planets in M-dwarf systems are
so close to their stars doesn't necessarily mean that they're fiery, hellish
worlds unsuitable for life, the astronomers say. Indeed, because M dwarfs are
small and cool, their temperate zone -- also known as the "habitable
zone," the region where liquid water might exist -- is also further
inward. Even though only the outermost of Kepler-32's five planets lies in its
temperate zone, many other M dwarf systems have more planets that sit right in
their temperate zones.
As for how the Kepler-32 system formed, no one
knows yet. But the team says its analysis places constraints on possible
mechanisms. For example, the results suggest that the planets all formed
farther away from the star than they are now, and migrated inward over time.
Like all planets, the ones around Kepler-32
formed from a proto-planetary disk -- a disk of dust and gas that clumped up
into planets around the star. The astronomers estimated that the mass of the
disk within the region of the five planets was about as much as that of three Jupiters.
But other studies of proto-planetary disks have shown that three Jupiter masses
can't be squeezed into such a tiny area so close to a star, suggesting to the
Caltech team that the planets around Kepler-32 initially formed farther out.
Another line of evidence relates to the fact
that M dwarfs shine brighter and hotter when they are young, when planets would
be forming. Kepler-32 would have been too hot for dust -- a key planet-building
ingredient -- to even exist in such close proximity to the star. Previously,
other astronomers had determined that the third and fourth planets from the
star are not very dense, meaning that they are likely made of volatile
compounds such as carbon dioxide, methane, or other ices and gases, the Caltech
team says. However, those volatile compounds could not have existed in the
hotter zones close to the star.
Finally, the Caltech astronomers discovered that
three of the planets have orbits that are related to one another in a very
specific way. One planet's orbital period lasts twice as long as another's, and
the third planet's lasts three times as long as the latter's. Planets don't
fall into this kind of arrangement immediately upon forming, Johnson says.
Instead, the planets must have started their orbits farther away from the star
before moving inward over time and settling into their current configuration.
"You look in detail at the architecture of
this very special planetary system, and you're forced into saying these planets
formed farther out and moved in," Johnson explains.
The implications of a galaxy chock full of
planets are far-reaching, the researchers say. "It's really fundamental
from an origins standpoint," says Swift, who notes that because M dwarfs
shine mainly in infrared light, the stars are invisible to the naked eye.
"Kepler has enabled us to look up at the sky and know that there are more
planets out there than stars we can see."
Original Source: California
Institute of Technology
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