Planet XO-3b has an internal source of heat, possibly from tidal heating, which is caused by the squeezing of the planet’s interior by the gravity of its parent star. This could be increased by the planet’s slightly elliptical orbit (shown on the right), meaning it’s more oval-shaped than circular. Credits: NASA/JPL-Caltech
The infrared observatory may help answer questions about planets outside
our solar system, or exoplanets, including how they form and what drives
weather in their atmospheres.
Two new studies using data from NASA’s retired Spitzer Space
Telescope shed light on giant exoplanets and brown dwarfs, objects that aren’t
quite stars but aren’t quite planets either. Both studies will be the focus of
virtual news conferences hosted by the American
Astronomical Society on Jan. 13.
One investigation shows that the weather on brown dwarfs – which form like
stars but don’t have sufficient mass to start burning hydrogen in their cores
as stars do – varies with age. Brown dwarfs and giant exoplanets are similar in
diameter, mass, and composition, so understanding the atmospheric properties of
one can provide insights about those of the other.
The second study belongs to a body of work looking at hot Jupiters – gas
exoplanets that orbit extremely close to their parent stars. How do these
massive planets come to be, and could there be subclasses of hot Jupiters with
different formation stories? To look for answers, the study authors looked at
exoplanet XO-3b, a rare example of a hot Jupiter observed while migrating
closer to its host star.
Exoplanet Analogs
Age often brings stability in humans, and that appears to be true for
cosmic objects as well. Johanna Vos, an astrophysicist at the American Museum
of Natural History in New York, will discuss a Spitzer survey published in the
Astrophysical Journal that found higher variability in the weather on young
brown dwarfs compared to old ones.
With regard to brown dwarfs, the word variability refers
to short-term changes in the intensity of different wavelengths of infrared
light coming from the object’s atmosphere. Astronomers think these variations
are caused by clouds, which reflect and absorb light in the atmosphere.
This illustration shows what clouds might look like in the atmosphere of a brown dwarf. Using NASA's retired Spitzer Space Telescope, scientists were able to detect clouds and other weather features in brown dwarf atmospheres. Credits: NASA/JPL-Caltech/IPAC/T. Pyle
High variability might indicate a major atmospheric feature, perhaps
like Jupiter’s Great Red
Spot – a storm larger than Earth that’s been swirling
for hundreds of years. It can also indicate a rapidly changing atmosphere,
which can have multiple causes such as major temperature differences in the
atmosphere or turbulence (sometimes caused by powerful winds).
Comparing the young brown dwarfs to previous Spitzer observations of older
brown dwarfs, the authors found that the young objects are more likely to show
atmospheric variation. They also found that variations are larger and more
dramatic in younger brown dwarfs. Vos and her colleagues attribute the
difference to the fact that brown dwarfs are puffier when they’re young but
become more compact as they age, which likely makes the atmosphere appear more
uniform.
Young brown dwarfs are similar in diameter, mass, and composition to giant
exoplanets primarily made of gas. But studying large exoplanets is complicated
by the close presence of their parent stars: The companion irradiates the
planet’s atmosphere, which changes the temperature, or even the chemistry, and
affects the weather. The bright light from the star also makes seeing the much
fainter planet more difficult.
Brown dwarfs, on the other hand, can act as a sort of control group and be observed
in isolation in space. The study’s authors plan to incorporate the new finding
into models of how brown dwarf and giant exoplanet atmospheres evolve with age.
Migrating Giants
Though hot Jupiters are the most
studied type of exoplanet, major questions remain about how they form. For
example, do these planets take shape far from their parent stars – at a
distance where it’s cold enough for molecules such as water to become solid –
or closer? The first scenario fits better with theories about how planets in
our own solar system are born, but what would drive these types of planets to
migrate so close to their parent stars remains unclear.
Lisa Dang, an exoplanet scientist at McGill University in Montreal, and her
colleagues used Spitzer data to study an exoplanet named XO-3b, which has an
eccentric (oval) orbit rather than the circular orbit of almost all other known
hot Jupiters. The eccentric orbit indicates XO-3b may have recently migrated
toward its parent star; if that’s the case, it will eventually settle into a
more circular orbit.
Observations by Gaia, an ESA (European Space Agency) space observatory, and
Spitzer both suggest the planet produces some of its own heat, but scientists
don’t know why. The Spitzer data also provides a map of the placessnet’s
climate patterns. It’s possible that the excess warmth is coming from the
planet’s interior, through a pro called tidal heating. The star’s gravitational
squeeze on the planet oscillates as the irregular orbit takes the planet
farther and then closer to the star. The resulting changes in interior pressure
produce heat.
For Dang, an unusual hot Jupiter provides an opportunity to test ideas
about which formation processes may produce certain characteristics in these
exoplanets. For example, could tidal heating in other hot Jupiters also be a
sign of recent migration? XO-3b alone won’t solve the mystery, but it serves as
an important test for emerging ideas about these scorching giants.
More About the Mission
The entire body of scientific data collected by Spitzer during its lifetime
is available to the public via the Spitzer data archive, housed at the Infrared
Science Archive at IPAC at Caltech in Pasadena, California. NASA's Jet
Propulsion Laboratory in Southern California managed the Spitzer Space
Telescope mission for NASA's Science Mission Directorate in Washington.
Science operations were conducted at the Spitzer Science Center at IPAC.
Spacecraft operations were based at Lockheed Martin Space in Littleton,
Colorado.
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