Article
Publicly Available
Novel nano-organisms from Australian sandstones
-
Philippa J.R. Uwins
,
Richard I. Webb
Published/Copyright:
November 13, 2015
Received: 1998-3-31
Accepted: 1998-7-31
Published Online: 2015-11-13
Published in Print: 1998-11-1
© 2015 by Walter de Gruyter Berlin/Boston
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- Alteration of microbially precipitated iron oxides and hydroxides
- Bacterial reduction of crystalline Fe3+ oxides in single phase suspensions and subsurface materials
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- Sulfur isotope variability in biogenic pyrite: Reflections of heterogeneous bacterial colonization?
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- Bioaccumulation of metals by lichens: Uptake of aqueous uranium by Peltigera membranacea as a function of time and pH
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- Effects of microbial activity on the δ18O of dissolved inorganic phosphate and textural features of synthetic apatites
- Feldspars as a source of nutrients for microorganisms
- Novel nano-organisms from Australian sandstones
- Experimental observations of the effects of bacteria on aluminosilicate weathering
- Manganite reduction by Shewanella putrefaciens MR-4
- Involvement of genes of the two-step protein secretion pathway in the transport of the manganese-oxidizing factor across the outer membrane of Pseudomonas putida strain GB-I
- Molecular phylogenetic analysis of a bacterial community in Sulphur River, Parker Cave, Kentucky
- The double helix meets the crystal lattice: The power and pitfalls of nucleic acid approaches for biomineralogical investigations
Articles in the same Issue
- Magnetite from magnetotactic bacteria: Size distributions and twinning
- Formation of Fe-silicates and Fe-oxides on bacterial surfaces in samples collected near hydrothermal vents on the Southern Explorer Ridge in the northeast Pacific Ocean
- Formation of single-domain magnetite by a thermophilic bacterium
- Alteration of microbially precipitated iron oxides and hydroxides
- Bacterial reduction of crystalline Fe3+ oxides in single phase suspensions and subsurface materials
- Microbial oxidation of pyrite: Experiments using microorganisms from an extreme acidic environment
- Sulfur isotope variability in biogenic pyrite: Reflections of heterogeneous bacterial colonization?
- Iron sulfides from magnetotactic bacteria: Structure, composition, and phase transitions
- Formation of lithified micritic laminae in modern marine stromatolites (Bahamas): The role of sulfur cycling
- Bioaccumulation of metals by lichens: Uptake of aqueous uranium by Peltigera membranacea as a function of time and pH
- Production of carbonate sediments by a unicellular green alga
- Primary structure of a soluble matrix protein of scallop shell: Implications for calcium carbonate biomineralization
- Effects of microbial activity on the δ18O of dissolved inorganic phosphate and textural features of synthetic apatites
- Feldspars as a source of nutrients for microorganisms
- Novel nano-organisms from Australian sandstones
- Experimental observations of the effects of bacteria on aluminosilicate weathering
- Manganite reduction by Shewanella putrefaciens MR-4
- Involvement of genes of the two-step protein secretion pathway in the transport of the manganese-oxidizing factor across the outer membrane of Pseudomonas putida strain GB-I
- Molecular phylogenetic analysis of a bacterial community in Sulphur River, Parker Cave, Kentucky
- The double helix meets the crystal lattice: The power and pitfalls of nucleic acid approaches for biomineralogical investigations
