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Evidence for reactive reduced phosphorus species in the early Archean oceanThe Natural Science Underlying Big HistoryRNA folding and catalysis mediated by iron (II)Origin and status of homologous proteins of biomineralization (biosilicification) in the taxonomy of phylogenetic domainsThe significance of Mg in prebiotic geochemistryGaia and her microbiome.The Origin of Life: Models and Data.Water-oxidation catalysis by manganese in a geochemical-like cycle.Is struvite a prebiotic mineral?Elemental geochemistry of sedimentary rocks at Yellowknife Bay, Gale crater, Mars.Nucleoside phosphorylation by the mineral schreibersiteNon-ureolytic calcium carbonate precipitation by Lysinibacillus sp. YS11 isolated from the rhizosphere of Miscanthus sacchariflorus.Carbonate Mineral Formation under the Influence of Limestone-Colonizing Actinobacteria: Morphology and Polymorphism.Life in the lithosphere, kinetics and the prospects for life elsewhere.Controlled hydroxyapatite biomineralization in an ~810 million-year-old unicellular eukaryote.Glycine Polymerization on Oxide Minerals.Review on the Role of Planetary Factors on Habitability.Magnetite Crystal Orientation in Magnetosome Chains.The power of crowding for the origins of life.Life = self-reproduction with variations?Pyrite surface environment drives molecular adsorption: cystine on pyrite(100) investigated by X-ray photoemission spectroscopy and low energy electron diffraction.Magnetite compensates for the lack of a pilin-associated c-type cytochrome in extracellular electron exchange.Catalytic Role of Manganese Oxides in Prebiotic Nucleobases Synthesis from Formamide.Chance, necessity and the origins of life: a physical sciences perspective.Microbial habitability of Europa sustained by radioactive sources.Hydrothermal synthesis as a route to mineralogically-inspired structures.The biological and geological contingencies for the rise of oxygen on Earth.Prebiotic synthesis of phosphoenol pyruvate by α-phosphorylation-controlled triose glycolysis.A Coevolutionary TaleMultianalytical approach to explain the darkening process of hematite pigment in paintings from ancient Pompeii after accelerated weathering experimentsPlate-tectonic evolution of the Earth: bottom-up and top-down mantle circulationThe origin of methane and biomolecules from a CO2 cycle on terrestrial planetsUsing Visual Exploratory Data Analysis to Facilitate Collaboration and Hypothesis Generation in Cross-Disciplinary ResearchMineralogical Diversity in Lake Pavin: Connections with Water Column Chemistry and Biomineralization ProcessesOxidation of manganese in an ancient aquifer, Kimberley formation, Gale crater, MarsElectronic and optical properties of theMg2−xFexSiO4spinel: From band insulator to Mott insulator
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Q22066256-B7063510-0E70-4BC4-A845-8C49048E7A1EQ27496060-D6365616-D6C5-49A6-9626-CEFD325A4E2AQ28484063-73D38199-5900-4E0A-AFA0-F4FD485390BBQ28680762-98711D5A-2217-416D-9BA2-02BA975C6575Q28710471-86503AA0-4409-4ABD-804F-BDD4E1F03D97Q31148108-B5F1ACDF-D5E3-4376-AC42-F9C72EC164A2Q31167730-EDDE1BAE-1294-4CB8-ACE1-3D734C8FDEC8Q34186654-BE2B707C-BE63-4E67-890E-855C418DD88AQ34295665-C3BDBBA1-AE92-4047-9165-796DB12840D3Q34390881-BD4358DC-6BF3-45BB-B61A-24F2B28AA29BQ36320936-A7F5971E-B0FC-4A0C-BCEB-4D3E220D2F17Q36383573-E7FE14ED-E17D-4F95-B684-63E18E6C3A3DQ36806053-96FC2ADF-257F-47AD-8BE1-B16445D02269Q37827250-5C3DE322-77E2-4185-9B2E-F1C253F0170BQ38637804-FE89C3B3-4613-452A-AA8D-CB4E86F9C37DQ38836340-F90898FC-BE4B-4337-93C0-A55471433E69Q38890979-C4B6D010-A083-4D50-ABF8-0B507504BFCEQ39206711-1B6C6CCD-5E1D-4D59-B19A-3D9B23069CFAQ44323111-8CD5320F-A86A-4043-A813-1E49BACCD9ACQ46017215-0141F786-D099-4D2A-94F5-0A3ED1866ECDQ46481071-2FADC694-E9C0-4A1F-8B04-F745E8E7D05CQ46906703-C36AD298-A3BE-4FE7-8D26-C6C55A75E46CQ47345689-A0A62AA2-BECB-4E8A-9CC1-9E867A420EE6Q47610461-4240EF10-9AEC-4222-9923-343FED4516B3Q47739706-BC646983-25D8-4E5C-B0C9-5C570EA9F87AQ51556318-2AA8DFE4-7FA4-4AF9-A74E-E8C5D0B4FAADQ53115735-65FEB538-9A1E-4285-B638-2DC0E7F2D52DQ55060055-91C82D9A-CF9C-4257-9CC3-40B167173050Q56805824-430BE12C-14DE-4D67-8632-39E4D70F41AFQ57084772-E4F099B4-DC7E-4174-B99E-2B8DADC61206Q57613115-627FB3B2-7185-4862-B4F8-F19C6548D8BBQ57682748-092BED73-8ED4-40B5-9BC8-BB3E08E999FBQ57852699-CFF25008-2500-4EE6-8CEC-1FCC87F032C0Q57892015-6FA90DD1-3CDB-4CA0-BBAA-23A5DC587F97Q57914990-F99D2D10-02A7-4263-BB89-461BE087BD21Q58809929-75882F7D-E2BC-4D2A-9BAD-29E47ACA2430
P2860
description
im November 2008 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в листопаді 2008
@uk
name
Mineral evolution
@en
Mineral evolution
@nl
type
label
Mineral evolution
@en
Mineral evolution
@nl
prefLabel
Mineral evolution
@en
Mineral evolution
@nl
P2093
P356
P1476
Mineral evolution
@en
P2093
D. A. Sverjensky
D. Papineau
J. M. Ferry
R. M. Hazen
R. T. Downs
W. Bleeker
P304
P356
10.2138/AM.2008.2955
P577
2008-11-01T00:00:00Z