space data telescope James Webb shows that WASP-107 b contains significantly less methane than expected and has a surprisingly large core, providing important information about its atmospheric chemistry and internal dynamics. The cotton candy-like planet WASP-107 b has surprisingly low amounts of methane and an extremely large core.

Discoveries based on data from space telescope James Webb marks the first measurements of the mass of an exoplanet’s core and will likely inform future studies of planetary atmospheres and interiors, an important aspect of the search for habitable worlds outside our solar system.

“Looking inside a planet hundreds of light-years away may seem nearly impossible, but when you know its mass, radius, atmospheric composition and temperature of its interior, you have everything you need to get an idea about it. Lead author David Singh, Bloomberg Professor Emeritus of Earth and Planetary Sciences at Johns Hopkins University, talked about what’s inside and how heavy this core is. “We can now do this for many different gas planets in different systems.”

recently published Nature The study shows that the planet contains a thousand times less methane than expected, and the core is 12 times larger than Earth’s.

Planetary composition and habitation potential

WASP-107 b, a giant planet surrounded by a cotton-soft, red-hot atmosphere, orbits a star about 200 light-years away. It is loose in structure: a world the size of Jupiter and only one-tenth the mass of a planet.

Although the planet contains methane, the building block of life on Earth, it is not considered habitable due to its proximity to its parent star and lack of a solid surface. However, it may hold important clues about the final stage of planetary evolution.

Methane and the mysteries of chemical dynamics

In a separate study published NatureOther scientists also observed methane gas with the Webb telescope and provided similar information about the size and density of the planet.

“We want to look at planets that have a lot of methane in their atmospheres, similar to the gas giants in our solar system,” Singh said. “This is where the story of WASP-107 b got really interesting, because we didn’t know why methane levels were so low.”

New measurements of methane show that the molecule breaks down into other compounds as it flows upward from the planet’s interior, interacting with a mixture of other chemicals and starlight in the upper atmosphere. The team also measured sulfur dioxide, water vapor, carbon dioxide and carbon monoxide and found that WASP-107 b contains more heavy elements than Uranus and Neptune.

Observational studies and future studies

Profiling the planet’s chemistry begins to reveal important pieces of the puzzle of how planetary atmospheres behave under extreme conditions, Singh said. His team will make similar observations of 25 more planets next year using the Webb telescope.

“We have never been able to study this mixing process in detail in the atmosphere of an exoplanet, so this will help us understand how these dynamic chemical reactions occur,” Singh said. “This is exactly what we need when we start looking at rocky planets and biomarker signatures.”

Internal heat sources and the influence of the atmosphere

Scientists suggest that the planet’s overestimated radius is the result of an internal heat source, said Zafar Rustamkulov, a Johns Hopkins planetary science doctoral student who led the study. By combining physical models of the atmosphere and interior with Webb’s data on WASP-107 b, the team elucidated how the planet’s thermodynamics affected its observed atmosphere.

“The planet has a hot core, and this heat source changes the chemistry of the gases more profoundly, but it also contributes to this strong, convective mixing coming from the inside,” Rustamkulov said. said. “We believe this heat causes a change in the chemistry of the gases, specifically breaking down methane to form increasing amounts of carbon dioxide and carbon monoxide.”

Current research and future experiments

The new findings also represent the clearest connection scientists have been able to establish between an exoplanet’s interior and its upper atmosphere, Rustamkulov said. Last year, the Webb telescope detected sulfur dioxide on another exoplanet called WASP-39 about 700 light-years away, providing the first evidence of an atmospheric compound formed by reactions caused by starlight.

The Johns Hopkins team is now focusing on what might sustain the hot core and thinks forces similar to those that drive tides in Earth’s oceans may be involved. They plan to test whether the planet is being pulled by its star and how this might explain the high temperature of the core.