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  • 551  (6)
  • Abies; Algal association; Araliaceoipollenites sp.; Artemisiaepollenites sp.; Botryococcus; Carpinuspollenites carpinoides; Caryapollenites sp.; CDRILL; Celtipollenites intrastructurus; Cercidiphyllites minimireticulatus; Chenopodipollis sp.; Compositae undifferentiated; Core drilling; Cyperaceaepollis sp.; DEPTH, sediment/rock; Ephedripites spp.; Ericipites spp.; Faguspollenites verus; Graminidites sp.; Green algae; Halophilic-xerophilic association; Ilexpollenites margaritatus; Inaperturopollenites spp.; Intratriporopollenites instructus; Juglandipollis sp.; Laevigatosporites haardtii; Leiotriletes sp.; Mesophytic understorey plant association + aquatic plants; Momipites punctatus; Monocolpopollenites sp.; Ovoidites; Perinomonoletes sp.; Periporopollenites sp.; Picea/Pinus undifferentiated; Platycaryapollenites sp.; Podocarpidites sp.; Polycolpopollenites hexaradiatus; Polyporopollenites spp.; Polyvestibulopollenites verus; Pterocaryapollenites sp.; Sample code/label; Sigmopollis sp.; Sparganiaceaepollenites sp.; Spores, trilete undifferentiated; Stereisporites sp.; SUBO_18; Swamp forest association; Temperate mixed mesophytic forest canopy association; Tetracolporopollenites sp.; Tetraporina; Triatriopollenites spp.; Tricolpopollenites asper; Tricolpopollenites liblarensis; Tricolpopollenites retiformis; Tricolporopollenites cingulum; Tricolporopollenites edmundii; Tricolporopollenites marcodurensis; Tricolporopollenites microreticulatus; Tricolporopollenites parmularius; Tricolporopollenites pseudocingulum; Tricolporopollenites retimuratus; Tricolporopollenites striatoreticulatus; Tricolporopollenites wackersdorfensis; Triporopollenites rhenanus; Trivestibulopollenites betuloides; Varia; Verrucatosporites spp.; Vitispollenites tener; Warm temperate forest association  (1)
  • 2015-2019  (7)
Collection
Keywords
Publisher
Language
Years
Year
  • 1
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    Relative frequencies of spore, pollen and algal taxa in core SUBO 18 (Enkingen) (2017)
    PANGAEA
    Details
    Publication Date: 2023-07-10
    Keywords: Abies; Algal association; Araliaceoipollenites sp.; Artemisiaepollenites sp.; Botryococcus; Carpinuspollenites carpinoides; Caryapollenites sp.; CDRILL; Celtipollenites intrastructurus; Cercidiphyllites minimireticulatus; Chenopodipollis sp.; Compositae undifferentiated; Core drilling; Cyperaceaepollis sp.; DEPTH, sediment/rock; Ephedripites spp.; Ericipites spp.; Faguspollenites verus; Graminidites sp.; Green algae; Halophilic-xerophilic association; Ilexpollenites margaritatus; Inaperturopollenites spp.; Intratriporopollenites instructus; Juglandipollis sp.; Laevigatosporites haardtii; Leiotriletes sp.; Mesophytic understorey plant association + aquatic plants; Momipites punctatus; Monocolpopollenites sp.; Ovoidites; Perinomonoletes sp.; Periporopollenites sp.; Picea/Pinus undifferentiated; Platycaryapollenites sp.; Podocarpidites sp.; Polycolpopollenites hexaradiatus; Polyporopollenites spp.; Polyvestibulopollenites verus; Pterocaryapollenites sp.; Sample code/label; Sigmopollis sp.; Sparganiaceaepollenites sp.; Spores, trilete undifferentiated; Stereisporites sp.; SUBO_18; Swamp forest association; Temperate mixed mesophytic forest canopy association; Tetracolporopollenites sp.; Tetraporina; Triatriopollenites spp.; Tricolpopollenites asper; Tricolpopollenites liblarensis; Tricolpopollenites retiformis; Tricolporopollenites cingulum; Tricolporopollenites edmundii; Tricolporopollenites marcodurensis; Tricolporopollenites microreticulatus; Tricolporopollenites parmularius; Tricolporopollenites pseudocingulum; Tricolporopollenites retimuratus; Tricolporopollenites striatoreticulatus; Tricolporopollenites wackersdorfensis; Triporopollenites rhenanus; Trivestibulopollenites betuloides; Varia; Verrucatosporites spp.; Vitispollenites tener; Warm temperate forest association
    Type: Dataset
    Format: text/tab-separated-values, 455 data points
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    DATA PANGAEA
  • 2
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    Characeae-derived carbonate deposits in Lake Ganau, Kurdistan Region, Iraq (2018)
    Springer Berlin Heidelberg | Berlin/Heidelberg
    Details
    Publication Date: 2021-03-29
    Description: Characeae, a family of calcifying green algae, are common in carbonate-rich freshwaters. The southwestern shoreline of Lake Ganau (Kurdistan Region, northeastern Iraq) harbors dense and thick mats of these algae (genus Chara). On the lake bottom and along the shore, carbonate sands and rocks rich in the remains of stems, branches, nodes, and whorls of Chara are deposited. These deposits show all stages of growth and degradation of characean algae, including replacement and lithification into limestone. The replacement of the fragments by fine-grained calcite preserved delicate microstructures of Chara, such as cortical walls, cell shape, inner and outer layers of the stems, and reproductive organs. Based on roundness, sorting, the degree of lithification, and preserved microstructures of the grains (fragments), three facies were recognized. The first is represented by a newly formed lime sand facies showing elongated grains, poor sorting, and reduced roundness, with pristine preservation of characean surface microstructures. The second is a weathered lime sand facies, which shows better sorting and good roundness, whereas internal structures of characean fragments are still well preserved. The third is comprised of a lithified lime sand facies (grainstone), with very well sorted and rounded grains, and poorly preserved external and internal structures of the characeans. As compared to the newly formed lime sand facies, the grainstone facies shows an increase in grain size by more than 30 %, owing to precipitation of micritic lamina of possible microbial origin. Eventually, the Characeae-derived lime sands are lithified into oolitic limestones with sparry calcite cement, forming a grainstone microfacies. The present study has important implications for the interpretation of pre-Quaternary environments, as it records all stages of the fossilization process of characean green algae and highlights the role of these algae in the formation of oolitic carbonate rocks.
    Keywords: Characeae; Chara; Ooids; Green algae; Carbonate sand; Freshwater carbonates; Facies ; 551 ; Earth Sciences; Sedimentology; Biogeosciences; Geochemistry; Paleontology; Ecology
    Language: English
    Type: article , publishedVersion
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  • 3
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    Unknown
    Assessing the utility of trace and rare earth elements as biosignatures in microbial iron oxyhydroxides (2018)
    Details
    Publication Date: 2021-03-29
    Description: Microbial iron oxyhydroxides are common deposits in natural waters, recent sediments, and mine drainage systems. Along with these minerals, trace and rare earth elements (TREE) are being accumulated within the mineralizing microbial mats. TREE patterns are widely used to characterize minerals and rocks, and to elucidate their evolution and origin. However, whether and which characteristic TREE signatures distinguish between a biological and an abiological origin of iron minerals is still not well-understood. Here we report on long-term flow reactor studies performed in the Tunnel of Äspö (Äspö Hard Rock Laboratory, Sweden). The development of microbial mats dominated by iron-oxidizing bacteria (FeOB), namely Mariprofundus sp. and Gallionella sp were investigated. The feeder fluids of the flow reactors were tapped at 183 and 290 m below sea-level from two brackish, but chemically different aquifers within the surrounding, ~1.8 Ga old, granodioritic rocks. The experiments investigated the accumulation and fractionation of TREE under controlled conditions of the subsurface continental biosphere, and enabled us to assess potential biosignatures evolving within the microbial iron oxyhydroxides. After 2 and 9 months, concentrations of Be, Y, Zn, Zr, Hf, W, Th, Pb, and U in the microbial mats were 103- to 105-fold higher than in the feeder fluids whereas the rare earth elements and Y (REE+Y) contents were 104- and 106-fold enriched. Except for a hydrothermally induced Eu anomaly, the normalized REE+Y patterns of the microbial iron oxyhydroxides were very similar to published REE+Y distributions of Archaean Banded Iron Formations (BIFs). The microbial iron oxyhydroxides from the flow reactors were compared to iron oxyhydroxides that were artificially precipitated from the same feeder fluid. Remarkably, these abiotic and inorganic iron oxyhydroxides show the same REE+Y distribution patterns. Our results indicate that the REE+Y mirror closely the water chemistry, but they do not allow to distinguish microbially mediated from inorganic iron precipitates. Likewise, all TREE studied showed an overall similar fractionation behavior in biogenic, abiotic, and inorganic iron oxyhydroxides. Exceptions are Ni and Tl, which were only accumulated in the microbial iron oxyhydroxides and may point to a potential utility of these elements as microbial biosignatures.
    Keywords: biosignatures; microbialmats; microbialironoxides; traceelements; rareearthelements; microbe–metalinteraction; bandedironformation ; 551
    Language: English
    Type: article , publishedVersion
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  • 4
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    Highly isotopically depleted isoprenoids ; molecular markers for ancient methane venting (2018)
    Details
    Publication Date: 2021-03-29
    Description: We propose that organic compounds found in a Miocene limestone from Marmorito (Northem Italy) are source markers for organic matter present in aneient methane vent systems (cold seeps). The limestone contains high concentrations of the tail-to-taillinked, acyclic C20 isoprenoid 2,6,11,15-tetramethylhexadecane (crocetane), a C25 homolog 2,6,10,15,19-pentamethylicosane (PME), and a distinctive glycerol ether lipid containing 3,7,1l,15-tetramethylhexadecyl (phytanyl-) moieties. The chemical structures of these biomarkers indicate a common origin from archaea. Their extreme1y l3C-depleted isotope compositions (813C "'" -108 to -115.6%0 PDB) suggest that the respective archaea have directly or indirectly introduced isotopically depleted, methane-derived carbon into their biomass. We postulate that a second major cluster of biomarkers showing heavier isotope values (8l3C "'" -88%0) is derived from sulfate-redueing bacteria (SRB). The observed biomarkers sustain the idea that methanogenic bacteria, in a syntrophic community with SRB, are responsible for the anaerobic oxidation of methane in marine sediments. Marmorito may thus represent a conceivable aneient scenario for methane consumption performed by a defined, two-membered bacterial consortium: (1) archaea that perform reversed methanogenesis by oxidizing methane and produeing CO2 and H2; and (2) SRB that consume the resulting H2. Furthermore, the respective organic molecules are, unlike other compounds, tightly bound to the crystalline carbonate phase. The Marmorito carbonates can thus be regarded as "cold seep microbialites" rather than mere "authigenic" carbonates.
    Keywords: Paläontologie: Allgemeines ; 551 ; VU 000 ; 38.20 ; 38.2
    Language: English
    Type: article , publishedVersion
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  • 5
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    Mid-chain branched alkanoic acids from "living fossil" demosponges: a link to ancient sedimentary lipids? (2018)
    Details
    Publication Date: 2021-04-25
    Description: The lipid assemblages of the "living fossil" stromatoporoid Astrosclera willeyana (Great Barrier Reet) and the demosponge Agelas aroides (Mediterranean Sea) were investigated. Large amounts of branched carboxylic acids are present in the sponges studied. These compounds include terminally branched carboxylic acids (isa -/anteisa-) and abundant mid-chain branched carboxylic acids (MBCA) wh ich are characterized by an intriguing variety of structural isomers present in the C 15- C25 range. The most prominent MBCA are comprised of isomeric methylhexadecanoic acids and methyloctadecanoic acids. A second cluster of MBCA includes methyldocosanoic acids and methyltetracosanoic acids, but other homologues are also present. Methyl branching points were generally observed between the w5- and w9-positions. These complex isomeric mixtures apparently derive from symbiotic bacteria living exclusively in demosponges. Comparison with hydrocarbon compositions of ancient carbonates reveals evidence that the MBCA found are potential lipid precursors of mid-chain branched monomethylalkanes often observed in fossil sediments and oils. As a working hypo thesis, we suggest that their bacterial source organisms have been widespread in the geological past, and are found " inherited" in the protective environment of distinctive sponge hosts in recent marine ecosystems. Furthermore, both sponges contain abundant linear, longchain C24- C26 dienoic "demospongic" acids. The demospongic acid distribution and the presence of phytanic acid in A. willeyana match the patterns found in A. aroides and other members of the Agelasida. These findings confirm the systematic position of A. willeyana within this demosponge taxon.
    Keywords: Paläontologie: Allgemeines ; 551 ; VU 000 ; 38.20 ; 38.2
    Language: English
    Type: article , publishedVersion
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  • 6
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    A Rare Glimpse of Paleoarchean Life: Geobiology of an Exceptionally Preserved Microbial Mat Facies from the 3.4 Ga Strelley Pool Formation, Western Australia. (2018)
    Details
    Publication Date: 2021-03-29
    Description: Paleoarchean rocks from the Pilbara Craton of Western Australia provide a variety of clues to the existence of early life on Earth, such as stromatolites, putative microfossils and geochemical signatures of microbial activity. However, some of these features have also been explained by non-biological processes. Further lines of evidence are therefore required to convincingly argue for the presence of microbial life. Here we describe a new type of microbial mat facies from the 3.4 Ga Strelley Pool Formation, which directly overlies well known stromatolitic carbonates from the same formation. This microbial mat facies consists of laminated, very fine-grained black cherts with discontinuous white quartz layers and lenses, and contains small domical stromatolites and wind-blown crescentic ripples. Light- and cathodoluminescence microscopy, Raman spectroscopy, and time of flight-secondary ion mass spectrometry (ToF-SIMS) reveal a spatial association of carbonates, organic material, and highly abundant framboidal pyrite within the black cherts. Nano secondary ion mass spectrometry (NanoSIMS) confirmed the presence of distinct spheroidal carbonate bodies up to several tens of μm that are surrounded by organic material and pyrite. These aggregates are interpreted as biogenic. Comparison with Phanerozoic analogues indicates that the facies represents microbial mats formed in a shallow marine environment. Carbonate precipitation and silicification by hydrothermal fluids occurred during sedimentation and earliest diagenesis. The deciphered environment, as well as the δ13C signature of bulk organic matter (-35.3‰), are in accord with the presence of photoautotrophs. At the same time, highly abundant framboidal pyrite exhibits a sulfur isotopic signature (δ34S = +3.05‰; Δ33S = 0.268‰; and Δ36S = -0.282‰) that is consistent with microbial sulfate reduction. Taken together, our results strongly support a microbial mat origin of the black chert facies, thus providing another line of evidence for life in the 3.4 Ga Strelley Pool Formation.
    Description: Open-Access Publikationsfonds 2016
    Keywords: Carbonates; Sulfur; Isotopes; Organic materials; Crystals; Paleoclimatology; Paleoenvironments; Quartz ; 551
    Language: English , English
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  • 7
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    Ideas and perspectives: hydrothermally driven redistribution and sequestration of early Archaean biomass – the “hydrothermal pump hypothesis” (2018)
    Details
    Publication Date: 2021-03-29
    Description: Archaean hydrothermal chert veins commonly contain abundant organic carbon of uncertain origin (abiotic vs. biotic). In this study, we analysed kerogen contained in a hydrothermal chert vein from the ca. 3.5 Ga Dresser Formation (Pilbara Craton, Western Australia). Catalytic hydropyrolysis (HyPy) of this kerogen yielded n-alkanes up to n-C22, with a sharp decrease in abundance beyond n-C18. This distribution ( n-C18) is very similar to that observed in HyPy products of recent bacterial biomass, which was used as reference material, whereas it differs markedly from the unimodal distribution of abiotic compounds experimentally formed via Fischer–Tropsch-type synthesis. We therefore propose that the organic matter in the Archaean chert veins has a primarily microbial origin. The microbially derived organic matter accumulated in anoxic aquatic (surface and/or subsurface) environments and was then assimilated, redistributed and sequestered by the hydrothermal fluids (“hydrothermal pump hypothesis”)
    Description: Open-Access-Publikationsfonds 2018
    Keywords: 551 ; early Archaean biomass; hydrothermal pump hypothesis
    Language: English
    Type: article , publishedVersion
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