6825 20240217082126.0 10.1051/0004-6361/202245655 DOI SCART-2024-0085 Konrad, Bjorn S. Large Interferometer For Exoplanets (LIFE) IX. Assessing the impact of clouds on atmospheric retrievals at mid-infrared wavelengths with a Venus-twin exoplanet 2023 Context. Terrestrial exoplanets in the habitable zone are likely a common occurrence. The long-term goal is to characterize the atmospheres of dozens of such objects. The Large Interferometer For Exoplanets (LIFE) initiative aims to develop a space-based mid-infrared (MIR) nulling interferometer to measure the thermal emission spectra of such exoplanets. Aims: We investigate how well LIFE could characterize a cloudy Venus-twin exoplanet. This allows us to: (1) test our atmospheric retrieval routine on a realistic non-Earth-like MIR emission spectrum of a known planet, (2) investigate how clouds impact retrievals, and (3) further refine the LIFE requirements derived in previous Earth-centered studies. Methods: We ran Bayesian atmospheric retrievals for simulated LIFE observations of a Venus-twin exoplanet orbiting a Sun-like star located 10 pc from the observer. The LIFESIM noise model accounted for all major astrophysical noise sources. We ran retrievals using different models (cloudy and cloud-free) and analyzed the performance as a function of the quality of the LIFE observation. This allowed us to determine how well the atmosphere and clouds are characterizable depending on the quality of the spectrum. Results: At the current minimal resolution (R = 50) and signal-to-noise (S /N = 10 at 11.2 μ m) requirements for LIFE, all tested models suggest a CO2-rich atmosphere (≥30% in mass fraction). Further, we successfully constrain the atmospheric pressure-temperature (P-T) structure above the cloud deck (P-T uncertainty ≤ ± 15 K). However, we struggle to infer the main cloud properties. Further, the retrieved planetary radius (Rpl), equilibrium temperature (Teq), and Bond albedo (AB) depend on the model. Generally, a cloud-free model performs best at the current minimal quality and accurately estimates Rpl, Teq, and AB. If we consider higher quality spectra (especially S/N = 20), we can infer the presence of clouds and pose first constraints on their structure. Conclusions: Our study shows that the minimal R and S/N requirements for LIFE suffice to characterize the structure and composition of a Venus-like atmosphere above the cloud deck if an adequate model is chosen. Crucially, the cloud-free model is preferred by the retrieval for low spectral qualities. We thus find no direct evidence for clouds at the minimal R and S/N requirements and cannot infer the thickness of the atmosphere. Clouds are only constrainable in MIR retrievals of spectra with S/N ≥ 20. The model dependence of our retrieval results emphasizes the importance of developing a community-wide best-practice for atmospheric retrieval studies. FED-tWIN STELLA/ FED-tWIN STELLA/ FED-tWIN STELLA NO Alei, Eleonora Quanz, Sascha P. Mollière, Paul Angerhausen, Daniel Fortney, Jonathan J. Hakim, Kaustubh Jordan, Sean Kitzmann, Daniel Rugheimer, Sarah Shorttle, Oliver Wordsworth, Robin Collaboration, the LIFE Astronomy & Astrophysics 673 2023 A94 kaustubh.hakim@ksb-orb.be https://doi.org/10.1051/0004-6361/202245655 4785793 http://publi2-as.oma.be/record/6825/files/Konrad2023LIFE.pdf 3570 http://publi2-as.oma.be/record/6825/files/Konrad2023LIFE.gif?subformat=icon icon 7252 http://publi2-as.oma.be/record/6825/files/Konrad2023LIFE.jpg?subformat=icon-180 icon-180 published in REFERD