A Comparative Simulation Study of Hot and Ultra-hot Jupiter Atmospheres using Different Ground-based High-resolution Spectrographs with Cross-correlation Spectroscopy

TL;DR

This study compares the capabilities of various ground-based spectrographs, including the upcoming E-ELT, in detecting molecules in hot Jupiter atmospheres through high-resolution spectroscopy and simulations.

Contribution

It provides a comprehensive simulation framework assessing the detectability of atmospheric molecules with different spectrographs, highlighting E-ELT's superior performance.

Findings

ANDES outperforms other spectrographs in molecular detection.

E-ELT can detect CO, NH3, and H2S with high confidence.

Simulations align well with real observations.

Abstract

In the era of state-of-the-art space-borne telescopes, high-resolution ground-based observation has emerged as a crucial method for characterizing exoplanets, providing essential insights into their atmospheric compositions. In the optical and NIR regions, high-resolution spectroscopy has been powerful for hot Jupiters (HJ) and ultra-hot Jupiters (UHJ) during their primary transits, as it can probe molecules with better sensitivity. Here, we focus on a comparative simulation study of WASP-76 b (UHJ) and WASP-77 A b (HJ) for different number of transits, utilizing three ground-based spectrographs (GIANO-B (TNG), CARMENES (CAHA), and ANDES (E-ELT)) with varying instrumental parameters, spectral coverages, and resolutions. We aim to evaluate the feasibility of the upcoming ground-based European Extremely Large Telescope (E-ELT) in probing molecules from planet atmospheres and how it surpasses other ground-based observatories in terms of detectability. With the 1-D model, petitCODE, we have self-consistently simulated the atmospheric pressure-temperature profiles, which are subsequently integrated into the 1-D chemical kinetics model, VULCAN, to evolve the atmospheric chemistry. High-resolution spectra are obtained by performing line-by-line radiative transfer using petitRADTRANS. Finally, we use the resulting spectra to assess the detectability (sigma_det) of molecular bands, employing the ground-based noise simulator SPECTR. Utilizing cross-correlation spectroscopy, we have successfully demonstrated the robust consistency between our simulation study and real-time observations for both planets. ANDES excels overall in molecular detection due to its enhanced instrumental architecture, reinforcing E-ELT's importance for studying exoplanet atmospheres. Additionally, our theoretical simulations predict the detection of CO, NH3, and H2S on WASP-76 b atmosphere with a sigma_det> 3.