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| A ‘hot Jupiter’ called HD 149026b, is about 3 times hotter than the rocky surface of Venus, the hottest planet in our solar system. Credit: NASA/JPL-Caltech |
Gas giants orbiting our sun show a clear pattern; the more massive the
planet, the lower the percentage of "heavy" elements (anything other than
hydrogen and helium) in the planet's atmosphere. But out in the galaxy, the
atmospheric compositions of giant planets do not fit the solar system trend,
an international team of astronomers has found.
Using NASA's James Webb Space Telescope (JWST), the researchers discovered
that the atmosphere of exoplanet HD149026b, a "hot Jupiter" orbiting a star
comparable to our sun, is super-abundant in the heavier elements carbon and
oxygen—far above what scientists would expect for a planet of its mass. In
addition, the diagnostic carbon-to-oxygen ratio of HD149026b, also known as
"Smertrios," is elevated relative to our solar system.
These findings, published in "High atmospheric metal enrichment for a
Saturn-mass planet" in Nature on March 27, are an important first step
toward obtaining similar measurements for a large sample of exoplanets in
order to search for statistical trends, the researchers said. They also
provide insight into planet formation.
"It appears that every giant planet is different, and we're starting to see
those differences thanks to JWST," said Jonathan Lunine, the David C. Duncan
Professor in the Physical Sciences in the College of Arts and Sciences and a
co-author of the study. "In this paper, we have determined how many
molecules there are relative to the primary component of the gas, which is
hydrogen, the most common element in the universe. That tells us quite a lot
about how this planet formed."
The giant planets of our solar system exhibit a nearly perfect correlation
between both overall composition and atmospheric composition and mass, said
Jacob Bean, professor of astronomy and astrophysics at the University of
Chicago and lead author of the paper. Extrasolar planets show a much greater
diversity of overall compositions, but scientists didn't know how varied
their atmospheric compositions were, until this analysis of HD149026b.
"We have shown definitively that the atmospheric compositions of giant
extrasolar planets do not follow the same trend that is so clear in the
solar system planets," Bean said. "Giant extrasolar planets show a wide
diversity in atmospheric compositions in addition to their wide diversity of
overall compositions."
Smertrios, for one, is super-enriched compared to its mass, Lunine said.
"It's the mass of Saturn, but its atmosphere seems to have as much as 27
times the amount of heavy elements relative to its hydrogen and helium that
we find in Saturn."
This ratio, called "metallicity" (even though it includes many elements that
are not metals), is useful for comparing a planet to its home star, or to
other planets in its system, Lunine said. Smertrios is the only planet known
in this particular planetary system.
Another key measurement is the ratio of carbon to oxygen in a planet's
atmosphere, which reveals the "recipe" of original solids in a planetary
system, Lunine said. For Smertrios, it's about 0.84—higher than in our solar
system. In our sun, it's a bit more than one carbon for every two oxygen
atoms (0.55).
"Together, these observations paint a picture of a planet-forming disk with
abundant solids that were carbon-rich," Lunine said. "HD149026b acquired
large amounts of this material as it formed."
While an abundance of carbon might seem favorable for chances of life, a
high carbon to oxygen ratio actually means less water on a planet or in a
planetary system—a problem for life as we know it.
Smertrios is an interesting first case of atmospheric composition for this
particular study, said Lunine, who has plans in place to observe five more
giant exoplanets in the coming year using JWST. Many more observations are
needed before astronomers can discover any patterns among giant planets or
in systems with multiple giant planets or terrestrial planets to the
compositional diversity astronomers are beginning to document.
"The origin of this diversity is a fundamental mystery in our understanding
of planet formation," Bean said. "Our hope is that further atmospheric
observations of extrasolar planets with JWST will quantify this diversity
better and yield constraints on more complex trends that might exist."
Reference:
Jacob L. Bean et al, High atmospheric metal enrichment for a Saturn-mass
planet, Nature (2023).
DOI: 10.1038/s41586-023-05984-y
Tags:
Space & Astrophysics