Now showing: Year 2008 projects that addressed Astrobiology Roadmap Objectives 5.2, 6.2
Roadmap Goal 5: Understand the evolutionary mechanisms and environmental limits of life
Objective 5.2: Co-evolution of microbial communities
Application of U-tube and fiber-optic distributed temperature sensor to characterize the chemical and physical properties of a deep permafrost and sub-permafrost environment at High Lake, Nunavut, Canada.
Biosignatures in chemosynthetic and photosynthetic systems
Carbon Flow Between Organisms in Complex Communities
DDF: Geomicrobiology of a Unique Ice-Sulfur Spring Ecosystem in the High Arctic
Describing the anaerobic thermophilic microbial community: A metagenomic strategy
Design, construction and testing of a Cavity-Ring Down Spectrometer for determination of the concentration and isotopic composition of methane
Ecology of a Hawaiian lava cave microbial mat
Environmental genomics reveals a single species ecosystem deep within the Earth.
Examination of the Microbial Diversity Found in Ice Cores (Brenchley)
Genome-Genome Integration: Symbiosis, genetic assimilation, and evolutionary innovation
High Lake Gossan deposit: An Arctic analogue for ancient Martian surficial processes?
Identifying microbial life at crustal rock-water interfaces
Laboratory Microbial Simulations: Astrobiological Signatures
Mars Forward Contamination Studies Utilizing a Mars Environmental Simulation Chamber
Mechanisms of Marine Microbial Community Structuring
Microbial Communities in Subpermafrost saline fracture water at the Lupin Au Mine, Nunavut, Canada
Microbial diversity and population structure studies in the Rio Tinto
Microbial diversity of a hypersaline microbial mat
Modeling Early Earth Environments
Molecular and Isotopic Microbial Community Analysis of Deep Subsurface Sediments
Molecular Signatures of Life on the Edge (DDF project)
Origin of multicellularity and complex land-based ecosystem
Planetary Surface and Interior Models and Super Earths
Planetary-Scale Transition from Abiotic to Biotic Nitrogen Cycle
Sediment-buried basement deep biosphere
Stromatolites in the Desert: Analogs to Other Worlds
Sulfur biogeochemistry of the Early Earth
The High Lakes Project (HLP)
Roadmap Goal 6: Understand the principles that will shape the future of life, both on Earth and beyond
Objective 6.2: Adaptation and evolution of life beyond Earth
5. Life in Extreme Environments
7. Astrobiotechnology
Design, construction and testing of a Cavity-Ring Down Spectrometer for determination of the concentration and isotopic composition of methane
Environmental genomics reveals a single species ecosystem deep within the Earth.
Examination of the Microbial Diversity Found in Ice Cores (Brenchley)
Expanding the List of Target Stars for Next Generation SETI Searches
Genome-Genome Integration: Symbiosis, genetic assimilation, and evolutionary innovation
Genomics of sulfidic cave extremophiles (Supplement to NNA04CC06A)
Icelandic subglacial lakes
Identifying microbial life at crustal rock-water interfaces
Interplanetary Pioneers
Mars Forward Contamination Studies Utilizing a Mars Environmental Simulation Chamber
Microbial Communities and Activities in the Deep Marine Subsurface
Planet Formation and Dynamical Modeling
Radiolytic oxidation of sulfide minerals as a source of sulfate and hydrogen to sustain microbial metabolism
Sediment-buried basement deep biosphere
The Diversity of the Original Prebiotic Soup: Re-Analyzing the Original Miller-Urey Spark Discharge Experiments
The High Lakes Project (HLP)
The Virtual Planetary Laboratory – The Life Modules - Photosynthesis
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