Exoplanetology: Exoplanets & Exomoons

Potential For Observing Geological Diversity From Mid-infrared Spectra Of Rocky Exoplanets

By Keith Cowing
Status Report
Nature Astronomy
November 19, 2024
Filed under , , , , , , ,
Potential For Observing Geological Diversity From Mid-infrared Spectra Of Rocky Exoplanets
Modelled planet-to-star fluxes The 15 Fp/F* simulations shown assume an airless, rocky exoplanet with a homogeneous surface temperature and a surface composition equivalent to each laboratory-measured rock sample in this study. R = 100. The PHOENIX stellar model of red dwarf LHS 3844 and the planetary parameters of its close-in rocky planet LHS 3844b were used as a representative star–planet system. The black body curve was calculated using the LHS 3844 PHOENIX stellar model and a planetary black body. Inset, Magnification of the Fp/F* models for three representative samples: relatively fresh, unaltered basalt LC10; amphibole-rich sample SE20; and serpentinized sample TO01. Dots are simulated MIRI LRS observations of a surface composed of sample SE20. High and low error bars show the estimated observation precision, assuming five eclipse observations of a planet like LHS 3844b, binned to R = 20 (Methods). The LRS simulation highlights the expected spectral deviation among the three basaltic samples near 10 μm. Symbols at top right are a reminder of which samples come from the same locality (as indicated by the symbol shape). The 15 modelled flux line colours correspond to symbol colours. Source data — Nature astronomy

The James Webb Space Telescope can potentially explore the geological diversity of the surfaces of rocky exoplanets, especially due to its access to mid-infrared wavelengths.

Here we investigate the level of geological detail that it could be possible to observe with the low-resolution spectroscopy and photometric modes of the mid-infrared instrument onboard the James Webb Space Telescope. We used new emissivity measurements of 15 basaltic samples between 2 μm and 25 μm to produce synthetic spectra and photometric fluxes.

We found that the mid-infrared instrument can, in principle, distinguish several specific mineralogical and bulk chemical signals among relatively similar rocks. In particular, hydrous minerals, such as amphibole and serpentine, which would signal the existence of past or present water, can have observable characteristics in both low-resolution spectroscopy observations (with the precision of 5 eclipses) and the integrated fluxes over mid-infrared instrument filter bandwidths (20–100 eclipses).

Photometric fluxes are also sensitive to bulk compositions (for example, wt% Al2O3), which reflect magmatic processes. Our work demonstrates the potential for the James Webb Space Telescope and future observatories to access a fuller picture of exoplanet surface geology.

astrobiology, astrogeology, astrochemistry,

Explorers Club Fellow, ex-NASA Space Station Payload manager/space biologist, Away Teams, Journalist, Lapsed climber, Synaesthete, Na’Vi-Jedi-Freman-Buddhist-mix, ASL, Devon Island and Everest Base Camp veteran, (he/him) 🖖🏻