The Experts below are selected from a list of 1068 Experts worldwide ranked by ideXlab platform
Fanelli E. - One of the best experts on this subject based on the ideXlab platform.
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Exo-Ocean Exploration with Deep-Sea Sensor and Platform Technologies
'Mary Ann Liebert Inc', 2020Co-Authors: Aguzzi J., Flexas M. M., Flögel S., Lo Iacono C., Tangherlini M., Costa C., Marini S., Bahamon N., Martini S., Fanelli E.Abstract:One of Saturn's largest moons, Enceladus, possesses a vast Extraterrestrial Ocean (i.e., exo-Ocean) that is increasingly becoming the hotspot of future research initiatives dedicated to the exploration of putative life. Here, a new bio-exploration concept design for Enceladus' exo-Ocean is proposed, focusing on the potential presence of organisms across a wide range of sizes (i.e., from uni- to multicellular and animal-like), according to state-of-the-art sensor and robotic platform technologies used in terrestrial deep-sea research. In particular, we focus on combined direct and indirect life-detection capabilities, based on optoacoustic imaging and passive acoustics, as well as molecular approaches. Such biologically oriented sampling can be accompanied by concomitant geochemical and Oceanographic measurements to provide data relevant to exo-Ocean exploration and understanding. Finally, we describe how this multidisciplinary monitoring approach is currently enabled in terrestrial Oceans through cabled (fixed) observatories and their related mobile multiparametric platforms (i.e., Autonomous Underwater and Remotely Operated Vehicles, as well as crawlers, rovers, and biomimetic robots) and how their modified design can be used for exo-Ocean exploration
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Exo-Ocean Exploration with Deep-Sea Sensor and Platform Technologies
'Mary Ann Liebert Inc', 2020Co-Authors: Aguzzi J., Flögel S., Lo Iacono C., Tangherlini M., Costa C., Marini S., Bahamon N., Martini S., Flexas M, Fanelli E.Abstract:International audienceOne of Saturn's largest moons, Enceladus, possesses a vast Extraterrestrial Ocean (i.e., exo-Ocean) that is increasingly becoming the hotspot of future research initiatives dedicated to the exploration of putative life. Here, a new bio-exploration concept design for Enceladus' exo-Ocean is proposed, focusing on the putative presence of organisms across a wide range of sizes (i.e., from uni-to multicellular and animal-like), according to state-of-the-art sensor and robotic platforms, technologies used in terrestrial deep-sea research. In particular, we focus on combined direct and indirect life-detection capabilities, based on optoacoustic imaging and passive acoustics, as well as molecular approaches. Such biologically oriented sampling can be accompanied by concomitant geochemical and Oceanographic measurements to provide data relevant to exo-Ocean exploration and understanding. Finally, we describe how this multidisciplinary monitoring approach is currently enabled in terrestrial Oceans through cabled (fixed) observatories and their related mobile multiparametric platforms (i.e., Autonomous Underwater and Remotely Operated Vehicles, as well as crawlers, rovers, and biomimetic robots) and how their modified design can be used for exo-Ocean exploration
Collins, Geoffrey C. - One of the best experts on this subject based on the ideXlab platform.
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The NASA Roadmap to Ocean Worlds
'Mary Ann Liebert Inc', 2020Co-Authors: Hendrix, Amanda R., Hurford, Terry A., Barge, Laura M., Bland, Michael T., Bowman, Jeff S., Brinckerhoff William, Buratti, Bonnie J., Cable, Morgan L., Castillo-rogez Julie, Collins, Geoffrey C.Abstract:In this article, we summarize the work of the NASA Outer Planets Assessment Group (OPAG) Roadmaps to Ocean Worlds (ROW) group. The aim of this group is to assemble the scientific framework that will guide the exploration of Ocean worlds, and to identify and prioritize science objectives for Ocean worlds over the next several decades. The overarching goal of an Ocean Worlds exploration program as defined by ROW is to "identify Ocean worlds, characterize their Oceans, evaluate their habitability, search for life, and ultimately understand any life we find." The ROW team supports the creation of an exploration program that studies the full spectrum of Ocean worlds, that is, not just the exploration of known Ocean worlds such as Europa but candidate Ocean worlds such as Triton as well. The ROW team finds that the confirmed Ocean worlds Enceladus, Titan, and Europa are the highest priority bodies to target in the near term to address ROW goals. Triton is the highest priority candidate Ocean world to target in the near term. A major finding of this study is that, to map out a coherent Ocean Worlds Program, significant input is required from studies here on Earth; rigorous Research and Analysis studies are called for to enable some future Ocean worlds missions to be thoughtfully planned and undertaken. A second finding is that progress needs to be made in the area of collaborations between Earth Ocean scientists and Extraterrestrial Ocean scientists
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The NASA Roadmap to Ocean Worlds
'Mary Ann Liebert Inc', 2019Co-Authors: Hendrix, Amanda R., Hurford, Terry A., Barge, Laura M., Bland, Michael T., Bowman, Jeff S., Brinckerhoff William, Buratti, Bonnie J., Cable, Morgan L., Castillo-rogez Julie, Collins, Geoffrey C.Abstract:In this article, we summarize the work of the NASA Outer Planets Assessment Group (OPAG) Roadmaps to Ocean Worlds (ROW) group. The aim of this group is to assemble the scientific framework that will guide the exploration of Ocean worlds, and to identify and prioritize science objectives for Ocean worlds over the next several decades. The overarching goal of an Ocean Worlds exploration program as defined by ROW is to "identify Ocean worlds, characterize their Oceans, evaluate their habitability, search for life, and ultimately understand any life we find." The ROW team supports the creation of an exploration program that studies the full spectrum of Ocean worlds, that is, not just the exploration of known Ocean worlds such as Europa but candidate Ocean worlds such as Triton as well. The ROW team finds that the confirmed Ocean worlds Enceladus, Titan, and Europa are the highest priority bodies to target in the near term to address ROW goals. Triton is the highest priority candidate Ocean world to target in the near term. A major finding of this study is that, to map out a coherent Ocean Worlds Program, significant input is required from studies here on Earth; rigorous Research and Analysis studies are called for to enable some future Ocean worlds missions to be thoughtfully planned and undertaken. A second finding is that progress needs to be made in the area of collaborations between Earth Ocean scientists and Extraterrestrial Ocean scientists.Open access articleThis item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu
Fanelli Emanuela - One of the best experts on this subject based on the ideXlab platform.
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Exo-Ocean exploration with deep-sea sensor and platform technologies
'Mary Ann Liebert Inc', 2020Co-Authors: Aguzzi Jacopo, Flexas Sbert, Maria Del Mar, Flögel Sasha, Lo Iacono Claudio, Tangherlini Michael, Costa Corrado, Marini Simone, Bahamón Rivera Nixon, Martini Séverine, Fanelli EmanuelaAbstract:La publicació final està disponible a Mary Ann Liebert, Inc., editorials http://dx.doi.org/10.1089/ast.2019.2129One of Saturn’s largest moons, Enceladus, possesses a vast Extraterrestrial Ocean (i.e., exo-Ocean) that is increasingly becoming the hotspot of future research initiatives dedicated to the exploration of putative life. Here, a new bio-exploration concept design for Enceladus’ exo-Ocean is proposed, focusing on the potential presence of organisms across a wide range of sizes (i.e., from uni- to multicellular and animal-like), according to state-of-the-art sensor and robotic platform technologies used in terrestrial deep-sea research. In particular, we focus on combined direct and indirect life-detection capabilities, based on optoacoustic imaging and passive acoustics, as well as molecular approaches. Such biologically oriented sampling can be accompanied by concomitant geochemical and Oceanographic measurements to provide data relevant to exo-Ocean exploration and understanding. Finally, we describe how this multidisciplinary monitoring approach is currently enabled in terrestrial Oceans through cabled (fixed) observatories and their related mobile multiparametric platforms (i.e., Autonomous Underwater and Remotely Operated Vehicles, as well as crawlers, rovers, and biomimetic robots) and how their modified design can be used for exo-Ocean exploration.Peer Reviewe
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Exo-Ocean Exploration with Deep-Sea Sensor and Platform Technologies
'Mary Ann Liebert Inc', 2020Co-Authors: Aguzzi Jacopo, Tangherlini M., Marini S., Lo Iacono Claudio, Costa Corrado, Martini Séverine, Flexas, María Del Mar, Floghel S., Bahamon Nixon, Fanelli EmanuelaAbstract:19 pages, 3 figures, 2 tablesOne of Saturn's largest moons, Enceladus, possesses a vast Extraterrestrial Ocean (i.e., exo-Ocean) that is increasingly becoming the hotspot of future research initiatives dedicated to the exploration of putative life. Here, a new bio-exploration concept design for Enceladus' exo-Ocean is proposed, focusing on the potential presence of organisms across a wide range of sizes (i.e., from uni- to multicellular and animal-like), according to state-of-the-art sensor and robotic platform technologies used in terrestrial deep-sea research. In particular, we focus on combined direct and indirect life-detection capabilities, based on optoacoustic imaging and passive acoustics, as well as molecular approaches. Such biologically oriented sampling can be accompanied by concomitant geochemical and Oceanographic measurements to provide data relevant to exo-Ocean exploration and understanding. Finally, we describe how this multidisciplinary monitoring approach is currently enabled in terrestrial Oceans through cabled (fixed) observatories and their related mobile multiparametric platforms (i.e., Autonomous Underwater and Remotely Operated Vehicles, as well as crawlers, rovers, and biomimetic robots) and how their modified design can be used for exo-Ocean explorationThis work was developed within the framework of the Tecnoterra Associate Unit (ICM-CSIC/UPC) and the following project activities: ARIM (Autonomous Robotic sea-floor Infrastructure for benthopelagic Monitoring; MartTERA ERA-Net Cofound; PIs: J.A., S.F., and L.T.), ARCHES (Autonomous Robotic Networks to Help Modern Societies; German Helmholtz Association; PI: S.F.), RESBIO (TEC2017-87861-R; Ministerio de Ciencia, Innovación y Universidades; PIs: J.d.R., J.A.). M.M.F.’s work was partially funded by the National Aeronautics and Space Administration through grant number NNX15AG42G. C.L.’s work was partially funded by the H2020-EU IF Maria Sklodowska Curie ‘‘HABISS’’ (Project 890815
Tangherlini M. - One of the best experts on this subject based on the ideXlab platform.
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Exo-Ocean Exploration with Deep-Sea Sensor and Platform Technologies
'Mary Ann Liebert Inc', 2020Co-Authors: Aguzzi J., Flexas M. M., Flögel S., Lo Iacono C., Tangherlini M., Costa C., Marini S., Bahamon N., Martini S., Fanelli E.Abstract:One of Saturn's largest moons, Enceladus, possesses a vast Extraterrestrial Ocean (i.e., exo-Ocean) that is increasingly becoming the hotspot of future research initiatives dedicated to the exploration of putative life. Here, a new bio-exploration concept design for Enceladus' exo-Ocean is proposed, focusing on the potential presence of organisms across a wide range of sizes (i.e., from uni- to multicellular and animal-like), according to state-of-the-art sensor and robotic platform technologies used in terrestrial deep-sea research. In particular, we focus on combined direct and indirect life-detection capabilities, based on optoacoustic imaging and passive acoustics, as well as molecular approaches. Such biologically oriented sampling can be accompanied by concomitant geochemical and Oceanographic measurements to provide data relevant to exo-Ocean exploration and understanding. Finally, we describe how this multidisciplinary monitoring approach is currently enabled in terrestrial Oceans through cabled (fixed) observatories and their related mobile multiparametric platforms (i.e., Autonomous Underwater and Remotely Operated Vehicles, as well as crawlers, rovers, and biomimetic robots) and how their modified design can be used for exo-Ocean exploration
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Exo-Ocean Exploration with Deep-Sea Sensor and Platform Technologies
'Mary Ann Liebert Inc', 2020Co-Authors: Aguzzi J., Flögel S., Lo Iacono C., Tangherlini M., Costa C., Marini S., Bahamon N., Martini S., Flexas M, Fanelli E.Abstract:International audienceOne of Saturn's largest moons, Enceladus, possesses a vast Extraterrestrial Ocean (i.e., exo-Ocean) that is increasingly becoming the hotspot of future research initiatives dedicated to the exploration of putative life. Here, a new bio-exploration concept design for Enceladus' exo-Ocean is proposed, focusing on the putative presence of organisms across a wide range of sizes (i.e., from uni-to multicellular and animal-like), according to state-of-the-art sensor and robotic platforms, technologies used in terrestrial deep-sea research. In particular, we focus on combined direct and indirect life-detection capabilities, based on optoacoustic imaging and passive acoustics, as well as molecular approaches. Such biologically oriented sampling can be accompanied by concomitant geochemical and Oceanographic measurements to provide data relevant to exo-Ocean exploration and understanding. Finally, we describe how this multidisciplinary monitoring approach is currently enabled in terrestrial Oceans through cabled (fixed) observatories and their related mobile multiparametric platforms (i.e., Autonomous Underwater and Remotely Operated Vehicles, as well as crawlers, rovers, and biomimetic robots) and how their modified design can be used for exo-Ocean exploration
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Exo-Ocean Exploration with Deep-Sea Sensor and Platform Technologies
'Mary Ann Liebert Inc', 2020Co-Authors: Aguzzi Jacopo, Tangherlini M., Marini S., Lo Iacono Claudio, Costa Corrado, Martini Séverine, Flexas, María Del Mar, Floghel S., Bahamon Nixon, Fanelli EmanuelaAbstract:19 pages, 3 figures, 2 tablesOne of Saturn's largest moons, Enceladus, possesses a vast Extraterrestrial Ocean (i.e., exo-Ocean) that is increasingly becoming the hotspot of future research initiatives dedicated to the exploration of putative life. Here, a new bio-exploration concept design for Enceladus' exo-Ocean is proposed, focusing on the potential presence of organisms across a wide range of sizes (i.e., from uni- to multicellular and animal-like), according to state-of-the-art sensor and robotic platform technologies used in terrestrial deep-sea research. In particular, we focus on combined direct and indirect life-detection capabilities, based on optoacoustic imaging and passive acoustics, as well as molecular approaches. Such biologically oriented sampling can be accompanied by concomitant geochemical and Oceanographic measurements to provide data relevant to exo-Ocean exploration and understanding. Finally, we describe how this multidisciplinary monitoring approach is currently enabled in terrestrial Oceans through cabled (fixed) observatories and their related mobile multiparametric platforms (i.e., Autonomous Underwater and Remotely Operated Vehicles, as well as crawlers, rovers, and biomimetic robots) and how their modified design can be used for exo-Ocean explorationThis work was developed within the framework of the Tecnoterra Associate Unit (ICM-CSIC/UPC) and the following project activities: ARIM (Autonomous Robotic sea-floor Infrastructure for benthopelagic Monitoring; MartTERA ERA-Net Cofound; PIs: J.A., S.F., and L.T.), ARCHES (Autonomous Robotic Networks to Help Modern Societies; German Helmholtz Association; PI: S.F.), RESBIO (TEC2017-87861-R; Ministerio de Ciencia, Innovación y Universidades; PIs: J.d.R., J.A.). M.M.F.’s work was partially funded by the National Aeronautics and Space Administration through grant number NNX15AG42G. C.L.’s work was partially funded by the H2020-EU IF Maria Sklodowska Curie ‘‘HABISS’’ (Project 890815
Marini S. - One of the best experts on this subject based on the ideXlab platform.
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Exo-Ocean Exploration with Deep-Sea Sensor and Platform Technologies
'Mary Ann Liebert Inc', 2020Co-Authors: Aguzzi J., Flexas M. M., Flögel S., Lo Iacono C., Tangherlini M., Costa C., Marini S., Bahamon N., Martini S., Fanelli E.Abstract:One of Saturn's largest moons, Enceladus, possesses a vast Extraterrestrial Ocean (i.e., exo-Ocean) that is increasingly becoming the hotspot of future research initiatives dedicated to the exploration of putative life. Here, a new bio-exploration concept design for Enceladus' exo-Ocean is proposed, focusing on the potential presence of organisms across a wide range of sizes (i.e., from uni- to multicellular and animal-like), according to state-of-the-art sensor and robotic platform technologies used in terrestrial deep-sea research. In particular, we focus on combined direct and indirect life-detection capabilities, based on optoacoustic imaging and passive acoustics, as well as molecular approaches. Such biologically oriented sampling can be accompanied by concomitant geochemical and Oceanographic measurements to provide data relevant to exo-Ocean exploration and understanding. Finally, we describe how this multidisciplinary monitoring approach is currently enabled in terrestrial Oceans through cabled (fixed) observatories and their related mobile multiparametric platforms (i.e., Autonomous Underwater and Remotely Operated Vehicles, as well as crawlers, rovers, and biomimetic robots) and how their modified design can be used for exo-Ocean exploration
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Exo-Ocean Exploration with Deep-Sea Sensor and Platform Technologies
'Mary Ann Liebert Inc', 2020Co-Authors: Aguzzi J., Flögel S., Lo Iacono C., Tangherlini M., Costa C., Marini S., Bahamon N., Martini S., Flexas M, Fanelli E.Abstract:International audienceOne of Saturn's largest moons, Enceladus, possesses a vast Extraterrestrial Ocean (i.e., exo-Ocean) that is increasingly becoming the hotspot of future research initiatives dedicated to the exploration of putative life. Here, a new bio-exploration concept design for Enceladus' exo-Ocean is proposed, focusing on the putative presence of organisms across a wide range of sizes (i.e., from uni-to multicellular and animal-like), according to state-of-the-art sensor and robotic platforms, technologies used in terrestrial deep-sea research. In particular, we focus on combined direct and indirect life-detection capabilities, based on optoacoustic imaging and passive acoustics, as well as molecular approaches. Such biologically oriented sampling can be accompanied by concomitant geochemical and Oceanographic measurements to provide data relevant to exo-Ocean exploration and understanding. Finally, we describe how this multidisciplinary monitoring approach is currently enabled in terrestrial Oceans through cabled (fixed) observatories and their related mobile multiparametric platforms (i.e., Autonomous Underwater and Remotely Operated Vehicles, as well as crawlers, rovers, and biomimetic robots) and how their modified design can be used for exo-Ocean exploration
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Exo-Ocean Exploration with Deep-Sea Sensor and Platform Technologies
'Mary Ann Liebert Inc', 2020Co-Authors: Aguzzi Jacopo, Tangherlini M., Marini S., Lo Iacono Claudio, Costa Corrado, Martini Séverine, Flexas, María Del Mar, Floghel S., Bahamon Nixon, Fanelli EmanuelaAbstract:19 pages, 3 figures, 2 tablesOne of Saturn's largest moons, Enceladus, possesses a vast Extraterrestrial Ocean (i.e., exo-Ocean) that is increasingly becoming the hotspot of future research initiatives dedicated to the exploration of putative life. Here, a new bio-exploration concept design for Enceladus' exo-Ocean is proposed, focusing on the potential presence of organisms across a wide range of sizes (i.e., from uni- to multicellular and animal-like), according to state-of-the-art sensor and robotic platform technologies used in terrestrial deep-sea research. In particular, we focus on combined direct and indirect life-detection capabilities, based on optoacoustic imaging and passive acoustics, as well as molecular approaches. Such biologically oriented sampling can be accompanied by concomitant geochemical and Oceanographic measurements to provide data relevant to exo-Ocean exploration and understanding. Finally, we describe how this multidisciplinary monitoring approach is currently enabled in terrestrial Oceans through cabled (fixed) observatories and their related mobile multiparametric platforms (i.e., Autonomous Underwater and Remotely Operated Vehicles, as well as crawlers, rovers, and biomimetic robots) and how their modified design can be used for exo-Ocean explorationThis work was developed within the framework of the Tecnoterra Associate Unit (ICM-CSIC/UPC) and the following project activities: ARIM (Autonomous Robotic sea-floor Infrastructure for benthopelagic Monitoring; MartTERA ERA-Net Cofound; PIs: J.A., S.F., and L.T.), ARCHES (Autonomous Robotic Networks to Help Modern Societies; German Helmholtz Association; PI: S.F.), RESBIO (TEC2017-87861-R; Ministerio de Ciencia, Innovación y Universidades; PIs: J.d.R., J.A.). M.M.F.’s work was partially funded by the National Aeronautics and Space Administration through grant number NNX15AG42G. C.L.’s work was partially funded by the H2020-EU IF Maria Sklodowska Curie ‘‘HABISS’’ (Project 890815
