Key Technologies and Instrumentation for Subsurface Exploration of Ocean Worlds

Dachwald, Bernd; Ulamec, Stephan; Postberg, F.; Sohl, F.; Vera, Jean Pierre Paul de; Waldmann, Christoph; Lorenz, Ralph D.; Zacny, K.; Hellard, Hugo; Biele, Jens; Rettberg, Petra

doi:10.1007/s11214-020-00707-5

Cited by 21 publications

(9 citation statements)

References 158 publications

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“…Another reason justifying the recent growth in robotic biomimicry research is space exploration. Such an exploration is not only oriented to Mars, but it actually includes the sub-surface oceans of Europa and Enceladus and other icy moons as equivalents to deep-sea terrestrial environments [ 38 , 53 , 79 , 80 ]. Proposed applications plan to use vectors to carry biomimicking probes for their delivery into specific terrestrial, atmospheric and aquatic environments, orienting biomimicking research toward the design of the structural hardware and toward the emulation of specific behavioral aspects.…”

Section: Discussionmentioning

confidence: 99%

“…Therefore, new robotic solutions are increasingly capable of operating without human supervision across ecosystems and under virtually any habitat condition [ 30 ] in a cooperative and intercommunicating mode [ 31 , 32 , 33 , 34 ]. Robots are being used for a wide range of agricultural, industrial, and broad environmental activities, e.g., [ 35 , 36 , 37 ], including forefront deep-sea and extra-terrestrial operational scenarios, e.g., [ 31 , 38 , 39 , 40 ]). For example, in the oceanic domains, robots’ data-gathering provides long-lasting time series on species presence and their abundances and environmental data in geographically and three-dimensionally extended water column-seabed scenarios [ 21 , 31 , 40 ].…”

Section: Introductionmentioning

confidence: 99%

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Research Trends and Future Perspectives in Marine Biomimicking Robotics

Aguzzi

Costa

Funari

et al. 2021

Sensors

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Mechatronic and soft robotics are taking inspiration from the animal kingdom to create new high-performance robots. Here, we focused on marine biomimetic research and used innovative bibliographic statistics tools, to highlight established and emerging knowledge domains. A total of 6980 scientific publications retrieved from the Scopus database (1950–2020), evidencing a sharp research increase in 2003–2004. Clustering analysis of countries collaborations showed two major Asian-North America and European clusters. Three significant areas appeared: (i) energy provision, whose advancement mainly relies on microbial fuel cells, (ii) biomaterials for not yet fully operational soft-robotic solutions; and finally (iii), design and control, chiefly oriented to locomotor designs. In this scenario, marine biomimicking robotics still lacks solutions for the long-lasting energy provision, which presently hinders operation autonomy. In the research environment, identifying natural processes by which living organisms obtain energy is thus urgent to sustain energy-demanding tasks while, at the same time, the natural designs must increasingly inform to optimize energy consumption.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Research Trends and Future Perspectives in Marine Biomimicking Robotics

Aguzzi

Costa

Funari

et al. 2021

Sensors

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“…In either event, our framework offers a simple heuristic for predicting what are the smallest organisms with gradient sensing and motility in a given domain, and this tool can be gainfully employed in the selection and design of apposite instrumentation. The latter subject is being vigorously pursued vis-à-vis Mars, Venus, and the subsurface ocean worlds of the Solar system (Ball et al, 2007;Hays et al, 2017;Vago et al, 2017;Chan et al, 2019;Stamenković et al, 2019;Dachwald et al, 2020;Carrier et al, 2020;Hein et al, 2020). It is not implausible, therefore, that the discovery of extraterrestrial life might progress a posse ad esse in the coming decades.…”

Section: Discussionmentioning

confidence: 99%

Theoretical constraints imposed by gradient detection and dispersal on microbial size in astrobiological environments

Lingam

2021

Preprint

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The capacity to sense gradients efficiently and acquire information about the ambient environment confers many advantages like facilitating movement toward nutrient sources or away from toxic chemicals. The amplified dispersal evinced by organisms endowed with motility is possibly beneficial in related contexts. Hence, the connections between information acquisition, motility, and microbial size are explored from an explicitly astrobiological standpoint. By using prior theoretical models, the constraints on organism size imposed by gradient detection and motility are elucidated in the form of simple heuristic scaling relations. It is argued that environments such as alkaline hydrothermal vents, which are distinguished by the presence of steep gradients, might be conducive to the existence of "small" microbes (with radii of 0.1 µm) in principle, when only the above two factors are considered; other biological functions (e.g., metabolism and genetic exchange) could, however, regulate the lower bound on microbial size and elevate it. The derived expressions are potentially applicable to a diverse array of settings, including those entailing solvents other than water; for example, the lakes and seas of Titan. The paper concludes with a brief exposition of how this formalism may be of practical and theoretical value to astrobiology.

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“…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). The largest drill being developed for a near-future flight opportunity is the 1 m long TRIDENT drill (Zacny et al 2021), expected to launch to the Moon in 2022, on a large lander or rover (450 -2000 kg; a very different class of mission than the 100 kg Philae).…”

Section: Sample Returnmentioning

confidence: 99%

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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Key Technologies and Instrumentation for Subsurface Exploration of Ocean Worlds

Cited by 21 publications

References 158 publications

Research Trends and Future Perspectives in Marine Biomimicking Robotics

Research Trends and Future Perspectives in Marine Biomimicking Robotics

Theoretical constraints imposed by gradient detection and dispersal on microbial size in astrobiological environments

Past and Future Comet Missions

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