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Home » New study reveals impact of stellar magnetic fields on exoplanet observations

New study reveals impact of stellar magnetic fields on exoplanet observations

In the constellation Virgo, 700 away from Earth, the planet WASP-39b orbits the star WASP-39. The gas giant, which takes little more than four days to complete one orbit, is one of the best-studied exoplanets. Shortly after its commissioning in July 2022, NASA's turned its high-precision gaze on the distant planet.

The data revealed evidence of large quantities of water vapor, , and even, for the first time, carbon dioxide in the atmosphere of WASP-39b. A minor sensation, but there is still one fly in the ointment: researchers have not yet succeeded in reproducing all the crucial details of the observations in model calculations. This stands in the way of an even more precise analysis of the data.

In the new study led by the MPS, the authors, including researchers from the Massachusetts Institute of Technology (U.S.), the Space Telescope Science Institute (U.S.), Keele University (United Kingdom), and the University of Heidelberg (Germany), show a way to overcome this obstacle.

“The problems arising when interpreting the data from WASP-39b are well known from many other exoplanets—regardless whether they are observed with Kepler, TESS, James Webb, or the future PLATO spacecraft,” explains MPS scientist Dr. Nadiia Kostogryz, first author of the new study. “As with other orbited by exoplanets, the observed light curve of WASP-39 is flatter than previous models can explain.”

Researchers define a light curve as a measurement of the brightness of a star over a longer period of time. The brightness of a star fluctuates constantly, for example, because its luminosity is subject to natural fluctuations. Exoplanets can also leave traces in the light curve. If an passes in front of its star as seen by an observer, it dims the starlight.

This is reflected in the light curve as a regularly recurring drop in brightness. Precise evaluations of such curves provide information about the size and orbital period of the planet. Researchers can also obtain information about the composition of the planet's atmosphere if the light from the star is split into its different wavelengths or colors.

Limb darkening in the Kepler passband. Credit: Nature Astronomy (2024). DOI: 10.1038/s41550-024-02252-5

A close look at a star's brightness distribution

The limb of a star, the edge of the stellar disk, plays a decisive role in the interpretation of its light curve. Just as in the case of the , the limb appears darker to the observer than the inner area. However, the star does not actually shine less brightly further out. “As the star is a sphere and its surface curved, we look into higher and therefore cooler layers at the limb than in the center,” explains co-author and MPS Director Prof. Dr. Laurent Gizon. “This area, therefore, appears darker to us,” he adds.

It is known that limb darkening affects the exact shape of the exoplanet signal in the light curve: The dimming determines how steeply the brightness of a star falls during a planetary transit and then rises again. However, it has not been possible to reproduce accurately using conventional models of the stellar atmosphere. The decrease in brightness was always less abrupt than the model calculations suggested.

“It was clear that we were missing a crucial piece of the puzzle to understand the exoplanets' signal precisely,” says MPS Director Prof. Dr. Sami Solanki, co-author of the current study.

is the missing piece of the puzzle

As the calculations published today show, the missing piece of the puzzle is the stellar magnetic field. Like the sun, many stars generate a magnetic field deep in their interior through enormous flows of hot . For the first time, the researchers were now able to include the magnetic field in their models of limb darkening.

They could show that the strength of the magnetic field has an important effect: The limb darkening is pronounced in stars with a weak magnetic field, while it is weaker in those with a strong magnetic field.

Solar limb darkening. Credit: Nature Astronomy (2024). DOI: 10.1038/s41550-024-02252-5

The researchers were also able to prove that the discrepancy between observational data and model calculations disappears if the star's magnetic field is included in the computations. To this end, the team turned to selected data from NASA's Kepler Space Telescope, which captured the light of thousands and thousands of stars from 2009 to 2018.

In the first step, the scientists modeled the atmosphere of typical Kepler stars in the presence of a magnetic field. In a second step, they then generated “artificial” observational data from these calculations. As a comparison with the real data showed, by including the magnetic field, the Kepler data is successfully reproduced.

The team also extended its considerations to data from the James Webb Space Telescope. The telescope is able to split the light of distant stars into its various wavelengths and thus search for the characteristic signs of certain molecules in the atmosphere of the discovered .

As it turns out, the magnetic field of the parent star influences the stellar limb darkening differently at different wavelengths—and should, therefore, be taken into account in future evaluations in order to achieve even more precise results.

From telescopes to models

“In the past decades and years, the way to move forward in exoplanet research was to improve the hardware, the space telescopes designed to search for and characterize new worlds. The James Webb Space Telescope has pushed this development to new limits,” says Dr. Alexander Shapiro, co-author of the current study and head of a research group at the MPS. “The next step is now to improve and refine the models to interpret this excellent data,” he adds.

To further advance this development, the researchers now want to extend their analyzes to stars that are clearly different from the sun. In addition, their findings offer the possibility of using the light curves of stars with exoplanets to infer the strength of the stellar magnetic field, which is otherwise often hard to measure.

The research is published in the journal Nature Astronomy.

Source: Max Planck Society