Scientists have created the first three-dimensional map of a distant planet’s atmosphere.
Using data from the James Webb Space Telescope (JWST) and a technique known as eclipse mapping, researchers discovered that there are different temperature zones in the atmosphere of exoplanet WASP-18b, a gas giant planet located about 400 light-years from Earth. The same process could soon help scientists map temperature changes and cloud structure on other distant planets, according to a study published Oct. 28 in the journal Nature Astronomy.
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WASP-18b has about 10 times the mass of Jupiter, and its year is only 23 hours long. Because it is tidally locked to the star, one side of the planet will always face the star, and the other side will always be dark.
As the planet begins to pass behind the star, the star blocks more and more of the light that the planet reflects, eventually obscuring the planet completely as seen from the solar system. Eclipse mapping takes advantage of this gradual change. By measuring how light from a planet changes as it disappears and emerges, scientists can determine the temperature of different regions and altitudes of the planet’s atmosphere.
“It’s very difficult because you have to look for changes where small parts of the Earth disappear and reappear in view,” Challenor said.
In the new study, scientists used different wavelengths of light to build a two-dimensional temperature map of the previous WASP-18b to create a more detailed 3D map of the atmosphere. For example, they used data on wavelengths absorbed by water to map the exoplanet’s moist upper atmosphere. Wavelengths that water did not absorb passed through to lower altitudes, allowing JWST to preferentially observe different levels of the planet’s atmosphere based on the wavelengths it was studying.
The research team discovered that there are two distinct temperature regions on the dayside of WASP-18b. There is a circular “hotspot” in the area directly facing the star that receives the most sunlight. Beyond that, there is a cooler ring that extends to the visible edge of the planet. This suggests that atmospheric winds cannot completely redistribute heat from the star throughout the planet.
Scientists also observed that hotspots have less water than the global average. The researchers suggested that this could mean that the temperature in the hot spot is high enough to tear apart water molecules in the atmosphere.
“We think this is evidence that the planet in this region is getting so hot that the water is starting to break down,” Challenor said. “It was predicted in theory, but it’s really exciting to actually see this in real observations.”
Additional measurements by JWST could improve the resolution of WASP-18b’s atmospheric map, allowing scientists to study the atmospheres of other similar gas giants.
“This new technique could be applied to many other planets that can be observed with the James Webb Space Telescope,” Challenor said. “It’s really exciting because we can start to understand exoplanets as a group in 3D.”
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