May have existed billions of years ago on Mars.Įxamples of such research include microbe-mineral interactions Terms of geology and biology are similar to those we hypothesize Referred to as Mars-analog sites, where conditions both in Prepare for the missions and to refine our ability to identifyĪnd correctly interpret putative morphologicalīiosignatures, research is currently done on Earth in places Special emphasis on morphological biosignatures. Mars 2020) to look for signs of extraterrestrial life, with Will focus on the general strategies that are used in theĬurrent and forthcoming robotic missions (MSL, ExoMars, Geochemical analysis, the search for life on Mars is in the Includes acquiring high-resolution images of geological samplesĪnd performing sophisticated mineralogical and Thanks to the new generation of rovers equipped with instrumentsĬapable of making “contact science”, which Key words: ExoMars mission, exobiology, biosignatures Possibly find evidence for past life on Mars, with special The presentation will focus on the strategies used during theĬurrent and forthcoming robotic missions to
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MORPHOLOGICAL BIOSIGNATURES ON MARS: WHAT TO EXPECT AND HOW TO Space Technical Ecosystem Enterprises (“ESTEE”) BLSS specialist *BLSS = Bioregenerative Life Support System Designed for long-duration missions (up to 1 year of Simulator, in order to enhance the preparation on Earth of This proof of concept is aimed to become a first step towards This prototype of a (semi-)closedĢ018 and its building is about to be started. Solution integrating existing and emergingīLSS* - related technologies. The Scorpius Prototype (SP1) is an autonomous terrestrial Towards a proof of concept of a closed habitat on-groundĭemonstration integrating main BLSS functions Timing constraints for Mars missions: example of communicationsīreaking through to a future unlimited in resources, time,ĭesign of a Mars Polar Research Base with a Crane System 24Ĭlément Chantebel, Léopold Comby, Maxime Lenormand, Anaisĭesigning a 10 ton Payload Martian Lander 25 Zero-Gravity: the first watchmaking complication of the space SEIS/INSIGHT: Towards the Seismic Discovering of Mars 14įrom the Earth’s stratosphere to flying on Mars 15Ĭurrent research in Time & Frequency and next generationĪrtificial Gravity during Earth-to-Mars Transit 17įirst results from the colour and stereo surface imaging systemĪtomic Clocks and Timing Systems in Global Navigation Satelliteįrom the Earth’s stratosphere to flying on Mars 20 Philippe Lognonné and the InSight/SEIS Team: Search for life on Mars, the ExoMars rover mission and the CLUPI “mass-production” constraints of a Colony project surge. The Interplanetary Transport System of SpaceX revisited 10īeyond human, technical and financial feasibility, Of the application of a terrestrial technology for the humanĪdvanced Electric Propulsion for Fast Manned Missions to Mars Industrie 4.0 technology for the building of a future Mars City: Humans on Mars will have to live according to both Martian &Ĭuriosity on Mars : What is new about organic molecules? 6
Morphological biosignatures on Mars: what to expect and how to 11 Jürgen Herholz: European Manned Space Projects 12 Jean-Luc Josset Search for life on Mars, the ExoMars rover mission and the CLUPI instrument 13 Philippe Lognonné and the InSight/SEIS Team: SEIS/INSIGHT: Towards the Seismic Discovering of Mars 14 Roland Loos: From the Earth’s stratosphere to flying on Mars 15ĮUROPEAN MARS CONVENTION 2018 – 26-28 OCT.
2018, L A C HAUX - DE -F ONDS, S WITZERLAND EMC18 Abstracts In alphabetical order Name title of presentation Page n° Théodore Besson: Scorpius Prototype 3 Tomaso Bontognali Morphological biosignatures on Mars: what to expect and how to prepare not to miss them 4 Pierre Brisson: Humans on Mars will have to live according to both Martian & Earth Time 5 Michel Cabane: Curiosity on Mars : What is new about organic molecules? 6 Antonio Del Mastro Industrie 4.0 technology for the building of a future Mars City: possibilities and limits of the application of a terrestrial technology for the human exploration of space 7 Angelo Genovese Advanced Electric Propulsion for Fast Manned Missions to Mars and Beyond 8 Olivia Haider: The AMADEE-18 Mars Simulation OMAN 9 Pierre-André Haldi: The Interplanetary Transport System of SpaceX revisited 10 Richard Heidman: Beyond human, technical and financial feasibility, “mass - production” constraints of a Colony project surge. E UROPEAN M ARS C ONVENTION 2018 – 26-28 O CT.
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