Triple F—a comet nucleus sample return mission

Küppers, M.; Keller, H. U.; Kührt, Ekkehard; A’Hearn, Michael F.; Altwegg, Kathrin; Bertrand, Reinhold; Busemann, H.; Capria, M. T.; Colangeli, L.; Davidsson, B.; Ehrenfreund, P.; Knollenberg, J.; Mottola, S.; Rathke, Andreas; Weiß, Peter; Zolensky, M. E.; Akim, E. L.; Basilevsky, A. T.; Galimov, É. M.; Герасимов, М. В.; Korablev, Oleg; Lomakin, I.; Marov, M. Ya.; Martynov, M. B.; Nazarov, M. A.; Захаров, А. В.; Zelenyǐ, L. M.; Aronica, A.; Ball, Andrew; Barbieri, C.; Bar‐Nun, A.; Benkhoff, J.; Biele, Jens; Biver, Nicolás; Blum, Jürgen; Bockelée‐Morvan, Dominique; Botta, Oliver; Bredehöft, Jan Hendrik; Capaccioni, F.; Charnley, Steven B.; Cloutis, E. A.; Cottin, Hervé; Cremonese, G.; Crovisier, J.; Crowther, S A; Epifani, E. Mazzotta; Esposito, F.; Ferrari, A.; Ferri, F.; Fulle, M.; Gilmour, J. D.; Goesmann, Fred; Gortsas, Nikolaos; Green, Simon; Groussin, O.; Grün, E.; Gutiérrez, P. J.; Hartogh, P.; Henkel, T.; Hilchenbach, M.; Ho, Tra‐Mi; Horneck, G.; Hviid, S. F.; Ip, W.-H.; Jäckel, A.; Jeßberger, E. K.; Kallenbach, R.; Kargl, Günter; Kömle, Norbert I.; Korth, A.; Kossacki, Konrad J.; Krause, Christian; Krüger, Harald; Li, Z.-Y.; Licandro, J.; Moreno, J. J. Lopez; Lowry, S. C.; Lyon, I. C.; Magni, G.; Mall, U.; Mann, Ingrid; Markiewicz, W. J.; Martins, Zita; Maurette, M.; Meierhenrich, Uwe J.; Mennella, V.; Ng, T. C.; Nittler, L. R.; Palumbo, P.; Pätzold, M.; Prialnik, Dina; Rengel, Miriam; Rickman, H.; Rodriguez, J.; Roll, R.; Rost, Detlef H.; Rotundi, A.; Sandford, Scott A.; Schönbächler, Maria; Sierks, H.; Srama, R.; Stroud, Rhonda M.; Szutowicz, S.; Tornow, Carmen; Ulamec, Stephan; Wallis, M. K.; Waniak, W.; Weissman, P. R.; Wieler, R.; Würz, Peter; Yung, Kai Leung; Zarnecki, J. C.

doi:10.1007/s10686-008-9115-8

Cited by 14 publications

(5 citation statements)

References 56 publications

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“…As (cryogenic) sample return remains the ultimate goal of comet exploration, a key technology requirement is the ability to land on the nucleus safely: either in a brief 'touch and go' maneuver, as used by the asteroid missions Hayabusa, Hayabusa 2 and OSIRIS-REx, and proposed at a comet by the Triple-F mission (Küppers et al 2009), or for a longer period of measurement/drilling. Landers also have a lot of potential to advance our knowledge of cometary activity, independent of any sample return attempt, through local measurements of the surface (micro-)physics, as was planned for Philae.…”

Section: Landing On the Nucleusmentioning

confidence: 99%

“…Drilling into the ice, and extracting an unaltered core, would be technically challenging. The SD2 drill on Philae was designed to reach a depth of 23 cm and retrieve material (but not an intact core) for composition analysis (Finzi et al 2007), while Triple-F proposed to extract 50 cm cores in touch-and-go landings (Küppers et al 2009). Neither of these has been successfully demonstrated at a comet; obtaining meters-long ice cores will require significant advances of these technologies, but may benefit from current developments for ocean world applications (Dachwald et al 2020).…”

Section: Sample Returnmentioning

confidence: 99%

“…There have been recent technological advances in cryogenic flight systems and instrumentation, as well as in cryogenic sample curation, handling, and analysis (Westphal et al 2021). Küppers et al (2009) proposed a passive system that would keep the sample below 133 K during cruise and 163 K during reentry, which would return a valuable sample at relatively low cost, even if some ices were lost. Bockelée-Morvan et al (2021) suggest that temperatures must be kept below 90 K, and pressure at 1 bar, to preserve most volatile ices (H 2 O, CO 2 , HCN).…”

Section: Sample Returnmentioning

confidence: 99%

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Past and Future Comet Missions

Snodgrass¹,

Feaga²,

Jones³

et al. 2022

Preprint

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We review the history of spacecraft encounters with comets, concentrating on those that took place in the recent past, since the publication of the Comets II book. This includes the flyby missions Stardust and Deep Impact, and their respective extended missions, the Rosetta rendezvous mission, and serendipitous encounters. While results from all of these missions can be found throughout this book, this chapter focuses on the questions that motivated each mission, the technologies that were required to answer these questions, and where each mission opened new areas to investigate. There remain a large number of questions that will require future technologies and space missions to answer; we also describe planned next steps and routes forward that may be pursued by missions that have yet to be selected, and eventually lead to cryogenic sample return of nucleus ices for laboratory study.

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Section: Landing On the Nucleusmentioning

confidence: 99%

Section: Sample Returnmentioning

confidence: 99%

Section: Sample Returnmentioning

confidence: 99%

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Past and Future Comet Missions

Snodgrass¹,

Feaga²,

Jones³

et al. 2022

Preprint

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“…In Europe, numerous industrial studies have been performed, in particular during phase A studies at ESA of the MarcoPolo and MarcoPolo-R asteroid sample return projects [20] for the Cosmic Vision programme (2015-2025), including sampling tool technology and the re-entry capsule (e.g., heat shield material development, aerodynamic stability). The Triple-F mission, a Comet Nucleus Cryogenic Sample return, has also been proposed to the Cosmic Vision programme, in collaboration with the Russian space agency [125].…”

Section: (Cryogenic) Sample Returnmentioning

confidence: 99%

AMBITION – comet nucleus cryogenic sample return

et al. 2021

Self Cite

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We describe the AMBITION project, a mission to return the first-ever cryogenically-stored sample of a cometary nucleus, that has been proposed for the ESA Science Programme Voyage 2050. Comets are the leftover building blocks of giant planet cores and other planetary bodies, and fingerprints of Solar System’s formation processes. We summarise some of the most important questions still open in cometary science and Solar System formation after the successful Rosetta mission. We show that many of these scientific questions require sample analysis using techniques that are only possible in laboratories on Earth. We summarize measurements, instrumentation and mission scenarios that can address these questions. We emphasize the need for returning a sample collected at depth or, still more challenging, at cryogenic temperatures while preserving the stratigraphy of the comet nucleus surface layers. We provide requirements for the next generation of landers, for cryogenic sample acquisition and storage during the return to Earth. Rendezvous missions to the main belt comets and Centaurs, expanding our knowledge by exploring new classes of comets, are also discussed. The AMBITION project is discussed in the international context of comet and asteroid space exploration.

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“…This craft was also implicated in the Deep Impact campaign, which saw a projectile directed at the surface of comet 9P/Tempel 1 in 2005 (with the subsequent impact plume being observed by the Deep Impact spacecraft itself), followed by a flyby in 2011 of Stardust (known by now as Stardust NExT) to observe the crater that had been formed on the comet's surface. An overview of the achievements of (most of) these missions can be found in, for instance, Kuppers et al [12].…”

Section: Space Missions To Cometsmentioning

confidence: 99%

On the attempts to measure water (and other volatiles) directly at the surface of a comet

Wright

Sheridan

Morgan

et al. 2017

Phil. Trans. R. Soc. A.

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The Ptolemy instrument on the Philae lander (of the Rosetta space mission) was able to make measurements of the major volatiles, water, carbon monoxide and carbon dioxide, directly at the surface of comet 67P/Churyumov–Gerasimenko. We give some background to the mission and highlight those instruments that have already given insights into the notion of water in comets, and which will continue to do so as more results are either acquired or more fully interpreted. On the basis of our results, we show how comets may in fact be heterogeneous over their surface, and how surface measurements can be used in a quest to comprehend the daily cycles of processes that affect the evolution of comets. This article is part of the themed issue ‘The origin, history and role of water in the evolution of the inner Solar System’.

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Triple F—a comet nucleus sample return mission

Cited by 14 publications

References 56 publications

Past and Future Comet Missions

Past and Future Comet Missions

AMBITION – comet nucleus cryogenic sample return

On the attempts to measure water (and other volatiles) directly at the surface of a comet

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