TY - JOUR
T1 - Calathus
T2 - a sample-return mission to Ceres
AU - Gassot, Oriane
AU - Panicucci, Paolo
AU - Acciarini, Giacomo
AU - Bates, Helena
AU - Caballero, Manel
AU - Cambianica, Pamela
AU - Dziewiecki, Maciej
AU - Dionnet, Zelia
AU - Enengl, Florine
AU - Gerig, Selina-Barbara
AU - Hessinger, Felix
AU - Kissick, Lucy
AU - Novak, Moritz
AU - Pellegrino, Carmine
AU - Pontoni, Angèle
AU - Ribeiro, Tânia M.
AU - Riegler, Clemens
AU - Berge, Nini
AU - Huber, Nikolaus
AU - Hynek, Richard
AU - Kędziora, Bartosz
AU - Kiss, Adam
AU - Martin, Maurice
AU - Montilla, Javier Navarro
PY - 2021/4/30
Y1 - 2021/4/30
N2 - Ceres, as revealed by NASA's Dawn spacecraft, is an ancient, crater-saturated body dominated by low-albedo clays. Yet, localised sites display a bright, carbonate mineralogy that may be as young as 2 Myr. The largest of these bright regions (faculae) are found in the 92 km Occator Crater, and would have formed by the eruption of alkaline brines from a subsurface reservoir of fluids. The internal structure and surface chemistry suggest that Ceres is an extant host for a number of the known prerequisites for terrestrial biota, and as such, represents an accessible insight into a potentially habitable “ocean world”. In this paper, the case and the means for a return mission to Ceres are outlined, presenting the Calathus mission to return to Earth a sample of the Occator Crater faculae for high-precision laboratory analyses. Calathus consists of an orbiter and a lander with an ascent module: the orbiter is equipped with a high-resolution camera, a thermal imager, and a radar; the lander contains a sampling arm, a camera, and an on-board gas chromatograph mass spectrometer; and the ascent module contains vessels for four cerean samples, collectively amounting to a maximum 40 g. Upon return to Earth, the samples would be characterised via high-precision analyses to understand the salt and organic composition of the Occator faculae, and from there to assess both the habitability and the evolution of a relict ocean world from the dawn of the Solar System.
AB - Ceres, as revealed by NASA's Dawn spacecraft, is an ancient, crater-saturated body dominated by low-albedo clays. Yet, localised sites display a bright, carbonate mineralogy that may be as young as 2 Myr. The largest of these bright regions (faculae) are found in the 92 km Occator Crater, and would have formed by the eruption of alkaline brines from a subsurface reservoir of fluids. The internal structure and surface chemistry suggest that Ceres is an extant host for a number of the known prerequisites for terrestrial biota, and as such, represents an accessible insight into a potentially habitable “ocean world”. In this paper, the case and the means for a return mission to Ceres are outlined, presenting the Calathus mission to return to Earth a sample of the Occator Crater faculae for high-precision laboratory analyses. Calathus consists of an orbiter and a lander with an ascent module: the orbiter is equipped with a high-resolution camera, a thermal imager, and a radar; the lander contains a sampling arm, a camera, and an on-board gas chromatograph mass spectrometer; and the ascent module contains vessels for four cerean samples, collectively amounting to a maximum 40 g. Upon return to Earth, the samples would be characterised via high-precision analyses to understand the salt and organic composition of the Occator faculae, and from there to assess both the habitability and the evolution of a relict ocean world from the dawn of the Solar System.
KW - sample return mission
KW - mission design
KW - astrobiology
KW - interplanetary mission
U2 - 10.1016/j.actaastro.2020.12.050
DO - 10.1016/j.actaastro.2020.12.050
M3 - Article
SN - 0094-5765
VL - 181
SP - 112
EP - 129
JO - Acta Astronautica
JF - Acta Astronautica
ER -