While there is currently a myriad of techniques used to both discover exoplanets and calculate their physical characteristics, could other methods be developed to overcome specific data errors? This is what a recent study published in Nature Astronomy hopes to address as an international team of researchers investigated how a star’s magnetic field can be used to ascertain additional data for an exoplanet, which is traditionally done using conventional exoplanet detection methods, specifically the transit detection method. This study holds the potential to help astronomers establish new methods for discovering and characterizing exoplanets throughout the cosmos.
For the transit method, an exoplanet passes in front of its parent star, causing its starlight to slightly decrease and has been instrumental in discovering and characterizing thousands of exoplanets. However, astronomers have also discovered that a star’s limb darkening, which is the observed edge of the star, causes errors in transit light curves for exoplanets, despite using state-of-the-art atmospheric models to predict observations.
For the study, the researchers focused on WASP-39b, which is a gas giant located approximately 700 light-years from Earth and has been studied in great detail using a myriad of space telescopes, and most recently with NASA’s James Webb Space Telescope (JWST). However, astronomers have discovered inconsistencies between models and observations, which this study hopes to overcome.
"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," said Dr. Nadiia Kostogryz, who is a scientist at the Max Planck Institute for Solar System Research and lead author of the study. "As with other stars orbited by exoplanets, the observed light curve of WASP-39 is flatter than previous models can explain," she adds.
To solve this conundrum, the researchers discovered that incorporating data on a star’s magnetic field helped alleviate, if not completely eliminate, the discrepancies between models and observational data. They successfully demonstrated this using past data from NASA’s Kepler Space Telescope and recent data obtained from JWST, discovering that incorporating the magnetic field data also helps provide more accurate atmospheric data, as well. Going forward, they hope this new method will help astronomers obtain more accurate light curve data for exoplanets.
Schematic demonstrating how incorporating a star's magnetic field data can help alleviate data errors in an exolpanet's light curve. (Credit: Max Planck Institute for Solar System Research/ hormesdesign.de)
How will a star’s magnetic field data help astronomers better understand exoplanets in the coming years and decades? Only time will tell, and this is why we science!
As always, keep doing science & keep looking up!
Sources: Nature Astronomy, EurekAlert!, Max Planck Institute for Solar System Research