This illustration represents how hot Jupiters of
different temperatures and different cloud compositions might appear to a
person flying over the dayside of these planets on a spaceship, based
on computer modeling. Credits: NASA/JPL-Caltech/University of Arizona/V. Parmentier. Full image and caption
The weather forecast for faraway, blistering planets called "hot
Jupiters" might go something like this: Cloudy nights and sunny days,
with a high of 2,400 degrees Fahrenheit (about 1,300 degrees Celsius, or
1,600 Kelvin).
These mysterious worlds are too far away for us to see clouds in
their atmospheres. But a recent study using NASA's Kepler space
telescope and computer modeling techniques finds clues to where such
clouds might gather and what they're likely made of. The study was
published in the
Astrophysical Journal and is also available on
the arXiv.
Hot Jupiters, among the first of the thousands of exoplanets (planets
outside our solar system) discovered in our galaxy so far, orbit their
stars so tightly that they are perpetually charbroiled. And while that
might discourage galactic vacationers, the study represents a
significant advance in understanding the structure of alien atmospheres.
Endless days, endless nights
Hot Jupiters are tidally locked, meaning one side of the planet
always faces its sun and the other is in permanent darkness. In most
cases, the "dayside" would be largely cloud-free and the "nightside"
heavily clouded, leaving partly cloudy skies for the zone in between,
the study shows.
"The cloud formation is very different from what we know in the solar
system," said Vivien Parmentier, a NASA Sagan Fellow and postdoctoral
researcher at the University of Arizona, Tucson, who was the lead author
of the study.
A "year" on such a planet can be only a few Earth days long, the time
the planet takes to whip once around its star. On a "cooler" hot
Jupiter, temperatures of, say, 2,400 degrees Fahrenheit might prevail.
But the extreme conditions on hot Jupiters worked to the scientists’ advantage.
"The day-night radiation contrast is, in fact, easy to model,"
Parmentier said. “[The hot Jupiters] are much easier to model than
Jupiter itself."
An eclipse, then blips
The scientists first created a variety of idealized hot Jupiters
using global circulation models -- simpler versions of the type of
computer models used to simulate Earth’s climate.
Then they compared the models to the light Kepler detected from real
hot Jupiters. Kepler, which is now operating in its K2 mission, was
designed to register the extremely tiny dip in starlight when a planet
passes in front of its star, which is called a "transit." But in this
case, researchers focused on the planets' "phase curves," or changes in
light as the planet passes through phases, like Earth’s moon.
Matching the modeled hot Jupiters to phase curves from real hot
Jupiters revealed which curves were caused by the planet’s heat, and
which by light reflected by clouds in its atmosphere. By combining
Kepler data with computer models, scientists were able to infer global
cloud patterns on these distant worlds for the first time.
The new cloud view allowed the team to draw conclusions about wind
and temperature differences on the hot Jupiters they studied. Just
before the hotter planets passed behind their stars -- in a kind of
eclipse -- a blip in the planet’s optical light curve revealed a "hot
spot" on the planet’s eastern side.
And on cooler eclipsing planets, a blip was seen just after the
planet re-emerged on the other side of the star, this time on the
planet’s western side.
The early blip on hotter worlds reveals that powerful winds were
pushing the hottest, cloud-free part of the atmosphere, normally found
directly beneath its sun, to the east. Meanwhile, on cooler worlds,
clouds could bunch up and reflect more light on the "colder," western
side of the planet, causing the post-eclipse blip.
"We’re claiming that the west side of the planet’s dayside is more cloudy than the east side," Parmentier said.
While the puzzling pattern has been seen before, this research was
the first to study all the hot Jupiters showing this behavior.
This led to another first. By figuring out how clouds are
distributed, which is intimately tied to the planet’s overall
temperature, scientists were able to determine what the clouds were
probably made of.
Just add manganese, and stir
Hot Jupiters are far too hot for water-vapor clouds like those on
Earth. Instead, clouds on these planets are likely formed as exotic
vapors condense to form minerals, chemical compounds like aluminum
oxide, or even metals, like iron.
The science team found that manganese sulfide clouds probably
dominate on "cooler" hot Jupiters, while silicate clouds prevail at
higher temperatures. On these planets, the silicates likely "rain out"
into the planet’s interior, vanishing from the observable atmosphere.
In other words, a planet’s average temperature, which depends on its
distance from its star, governs the kinds of clouds that can form. That
leads to different planets forming different types of clouds.
"Cloud composition changes with planet temperature," Parmentier said.
"The offsetting light curves tell the tale of cloud composition. It’s
super interesting, because cloud composition is very hard to get
otherwise."
The new results also show that clouds are not evenly distributed on hot Jupiters, echoing previous findings from
NASA’s Spitzer Space Telescope suggesting that different parts of hot Jupiters have vastly different temperatures.
The new findings come as we mark the 21st anniversary of exoplanet
hunting. On Oct. 6, 1995, a Swiss team announced the discovery of
51 Pegasi b,
a hot Jupiter that was the first planet to be confirmed in orbit around
a sun-like star. Parmentier and his team hope their revelations about
the clouds on hot Jupiters could bring more detailed understanding of
hot Jupiter atmospheres and their chemistry, a major goal of exoplanet
atmospheric studies.
NASA Ames manages the Kepler and K2 missions for NASA's Science
Mission Directorate. NASA's Jet Propulsion Laboratory in Pasadena,
California, managed Kepler mission development. Ball Aerospace &
Technologies Corporation operates the flight system with support from
the Laboratory for Atmospheric and Space Physics at the University of
Colorado at Boulder. This work was performed in part under contract with
JPL, funded by NASA through the Sagan Fellowship Program, executed by
the NASA Exoplanet Science Institute.
Elizabeth Landau
Jet Propulsion Laboratory, Pasadena, Calif.
818-354-6425
elizabeth.landau@jpl.nasa.gov
Michele Johnson
Ames Research Center, Moffett Field, Calif.
650-604-6982
michele.johnson@nasa.gov
Written by Pat Brennan