November 22, 2024

“Cosmic Thermometer” Detected on WASP-31b – A Giant Leap in Exoplanet Research

New Discoveries on Hot Jupiter WASP-31b
Now, Flagg and a Cornell-led group of researchers have verified, utilizing high-resolution spectral observations, the existence of chromium hydride in an exoplanet environment of the hot Jupiter WASP-31b, unlocking to utilize this temperature-sensitive molecule types as a “thermometer” to determine the temperature level and other qualities in exoplanets.
Flagg is lead author of “ExoGemS Detection of a Metal Hydride in an Exoplanet Atmosphere at High Spectral Resolution,” published on August 16 in The Astrophysical Journal Letters. Co-authors consist of: Ray Jayawardhana, the Hans A. Bethe Professor and professor of astronomy (A&S); Jake D. Turner, Hubble Research Fellow in the Cornell Center for Astrophysics & & Planetary Science; Ryan J. MacDonald, formerly a research associate at the Carl Sagan Institute and now a NASA Sagan Fellow at the University of Michigan; and Adam Langeveld, postdoctoral researcher in astronomy (A&S).
Chromium hydride has actually no previous validated detections in any exoplanet, and this marks the very first detection of a metal hydride from a high-resolution exoplanet spectrum, the researchers wrote.
Significance of the Discovery
The definitive detection of metal hydrides in WASP-31b is an important development in the understanding of hot huge world atmospheres, Flagg stated, although the discovery does not give brand-new details about the individual world. Found in 2011, WASP-31b orbits an F5 star once every 3.4 days. It has an exceptionally low density, even for a huge planet, and the new research study verifies its equilibrium temperature level at 1,400 Kelvin– in variety for chromium hydride.
” Chromium hydride particles are very temperature level delicate,” Flagg said. Theres only a specific temperature level range, about 1,200 to 2,200 Kelvin, where chromium hydride is seen in large abundances.”
In our planetary system, the only identified incident of this molecule remains in sunspots, Flagg stated: the sun is too hot (around 6,000 K on the surface area) and all other objects are too cool.
Methods and Instruments Used
In her research, Flagg uses high-resolution spectroscopy to detect and analyze exoplanet environments, comparing the overall light from the system when the world is to the side of the star against when the world remains in front of the star, obstructing a few of the stars light. Certain aspects obstruct more light at certain wavelengths and less light at other wavelengths, revealing what elements remain in the world.
We combine them using numerous analytical methods, using a design template– an approximate idea of what the spectrum looks like– and we compare it to the information and we match it up. We attempt all the different templates, and in this case, the chromium hydride template produced a signal.”
Chromium is uncommon, even at the best temperature, so researchers require delicate instruments and telescopes, Flagg stated.
To examine WASP-31b, the scientists used high-resolution spectra from one new observation in March 2022 as part of the Exoplanets with Gemini Spectroscopy study from Hawaiis Maunakea, utilizing Gemini Remote Access to CFHT ESPaDOnS Spectrograph (GRACES). They supplemented the GRACES information with archival data taken in 2017, which was not intended to look for metal hydrides.
Looking Forward
” Part of our information for this paper was old information that was on the very edge of the data set. You would not have searched for it,” Flagg stated. She is now on the lookout for chromium hydride and other metal hydrides in other exoplanets– and the evidence may currently exist.
” Im hoping that this paper will motivate other scientists to look in their data for chromium hydride and other metal hydrides,” Flagg said. “We think it needs to be there. Hopefully, well get more information that will appropriate for searching for chromium hydride and eventually develop a sample size to search for trends.”
Reference: “ExoGemS Detection of a Metal Hydride in an Exoplanet Atmosphere at High Spectral Resolution” by Laura Flagg, Jake D. Turner, Emily Deibert, Andrew Ridden-Harper, Ernst de Mooij, Ryan J. MacDonald, Ray Jayawardhana, Neale Gibson, Adam Langeveld and David Sing, 16 August 2023, The Astrophysical Journal Letters.DOI: 10.3847/ 2041-8213/ ace529.

Astronomers have actually confirmed the existence of chromium hydride in the environment of the hot Jupiter WASP-31b using high-resolution spectral observations. This molecule, abundant just in between 1,200-2,000 degrees Kelvin, has the possible to function as a “thermometer” for exoplanets.
Chromium hydride, found in the temperature variety of 1,200-2,000 degrees Kelvin, has been detected in the hot Jupiter WASP-31bs atmosphere. This discovery paves the way for the particle to be used as a “thermometer” for exoplanets.
Chromium hydride (CrH), a particle thats fairly uncommon and especially delicate to temperature level, works as a “thermometer for stars,” according to astronomer Laura Flagg. This is due to the fact that its plentiful just in a narrow variety in between 1,200-2,000 degrees Kelvin.
Flagg, a research partner in astronomy at Cornell Universitys College of Arts and Sciences (A&S), has actually used this and other metal hydrides to figure out the temperature level of cool stars and brown dwarfs. In theory, she stated, chromium hydride could do the exact same for hot Jupiter exoplanets, which are comparable in temperature to brown overshadows– if these particular particles exist in exoplanet environments. Previous research study, at low resolution, hinted that they are.

In theory, she stated, chromium hydride might do the exact same for hot Jupiter exoplanets, which are similar in temperature level to brown dwarfs– if these specific particles are present in exoplanet atmospheres. It has an extremely low density, even for a giant world, and the new research study validates its equilibrium temperature at 1,400 Kelvin– in variety for chromium hydride.
” Chromium hydride molecules are very temperature level sensitive,” Flagg said. She is now on the lookout for chromium hydride and other metal hydrides in other exoplanets– and the proof may already exist.
” Im hoping that this paper will motivate other scientists to look in their data for chromium hydride and other metal hydrides,” Flagg said.