Mission Architecture to Characterize Habitability of Venus Cloud Layers via an Aerial Platform
Author(s)
Agrawal, Rachana; Buchanan, Weston P.; Arora, Archit; Girija, Athul P.; De Jong, Maxim; Seager, Sara; Petkowski, Janusz J.; Saikia, Sarag J.; Carr, Christopher E.; Grinspoon, David H.; Longuski, James M.; on behalf of Venus Life Finder Mission Team,; ... Show more Show less
Downloadaerospace-09-00359.pdf (4.476Mb)
Publisher with Creative Commons License
Publisher with Creative Commons License
Creative Commons Attribution
Terms of use
Metadata
Show full item recordAbstract
Venus is known for its extreme surface temperature and its sulfuric acid clouds. But the cloud layers on Venus have similar temperature and pressure conditions to those on the surface of Earth and are conjectured to be a possible habitat for microscopic life forms. We propose a mission concept to explore the clouds of Venus for up to 30 days to evaluate habitability and search for signs of life. The baseline mission targets a 2026 launch opportunity. A super-pressure variable float altitude balloon aerobot cycles between the altitudes of 48 and 60 km, i.e., primarily traversing the lower, middle, and part of the upper cloud layers. The instrument suite is carried by a gondola design derived from the Pioneer Venus Large Probe pressure vessel. The aerobot transmits data via an orbiter relay combined with a direct-to-Earth link. The orbiter is captured into a 6-h retrograde orbit with a low, roughly 170-degree, inclination. The total mass of the orbiter and entry probe is estimated to be 640 kg. An alternate concept for a constant float altitude balloon is also discussed as a lower complexity option compared to the variable float altitude version. The proposed mission would complement other planned missions and could help elucidate the limits of habitability and the role of unknown chemistry or possibly life itself in the Venus atmosphere.
Date issued
2022-07-06Department
Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary SciencesPublisher
Multidisciplinary Digital Publishing Institute
Citation
Aerospace 9 (7): 359 (2022)
Version: Final published version