Now Reading: TSD: An Inverse Problem Approach For Recovering The Exoplanetary Atmosphere Transmission Spectrum From High-resolution Spectroscopy
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TSD: An Inverse Problem Approach For Recovering The Exoplanetary Atmosphere Transmission Spectrum From High-resolution Spectroscopy
TSD: An Inverse Problem Approach For Recovering The Exoplanetary Atmosphere Transmission Spectrum From High-resolution Spectroscopy
A wavelength fragment of the simulated seven-transit observations of WASP-107 b with VLT/CRIRES+. The wavelength range (horizontal axis, nm) corresponds to the part of spectral order 24 (second order from the bottom) that falls on the middle detector, and the vertical axis is the time dimension starting with exposure 0 of the first observation at the bottom. Horizontal bands correspond to individual transits with 50-64 spectra per transit, with the influence of airmass and variable slit losses affecting the flux level between adjacent exposures. One can clearly distinguish telluric (constant in wavelength) and stellar (shifting with barycentric velocity) lines and notice the variation of telluric absorption strength between transits. — astro-ph.EP
Our ability to observe, detect, and characterize exoplanetary atmospheres has grown by leaps and bounds over the last 20 years, aided largely by developments in astronomical instrumentation; improvements in data analysis techniques; and an increase in the sophistication and availability of spectroscopic models.
Over this time, detections have been made for a number of important molecular species across a range of wavelengths and spectral resolutions. Ground-based observations at high resolution are particularly valuable due to the high contrast achievable between the stellar spectral continuum and the cores of resolved exoplanet absorption features.
However, the model-independent retrieval of such features remains a major hurdle in data analysis, with traditional methods being limited by both the choice of algorithm used to remove the non-exoplanetary components of the signal, as well as the accuracy of model template spectra used for cross-correlation.
Here we present a new algorithm TSD (Transmission Spectroscopy Decomposition) formulated as an inverse problem in order to minimize the number of assumptions and theoretically modelled components included in the retrieval.
Instead of cross-correlation with pre-computed template exoplanet spectra, we rely on high spectral resolution and instrument stability to distinguish between the stellar, exoplanetary, and telluric components and velocity frames in the sequence of absorption spectra taken during multiple transits.
We demonstrate the performance of our new method using both simulated and real K band observations from ESO’s VLT/CRIRES+ instrument, and present results obtained from two transits of the highly-inflated super-Neptune WASP-107 b which orbits a nearby K7V star.
Nikolai Piskunov, Adam D. Rains, Linn Boldt-Christmas
Comments: 26 pages, 8 figures. Submitted to ApJ. Comments are welcome
Subjects: Earth and Planetary Astrophysics (astro-ph.EP); Instrumentation and Methods for Astrophysics (astro-ph.IM)
Cite as: arXiv:2509.12737 [astro-ph.EP] (or arXiv:2509.12737v1 [astro-ph.EP] for this version)
https://doi.org/10.48550/arXiv.2509.12737
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Submission history
From: Linn Boldt-Christmas
[v1] Tue, 16 Sep 2025 06:51:45 UTC (3,350 KB)
https://arxiv.org/abs/2509.12737
Astrobiology,
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