2010
DOI: 10.1098/rsta.2010.0024
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Mineral–microbe interactions in deep-sea hydrothermal systems: a challenge for Raman spectroscopy

Abstract: In deep-sea hydrothermal environments, steep chemical and thermal gradients, rapid and turbulent mixing and biologic processes produce a multitude of diverse mineral phases and foster the growth of a variety of chemosynthetic micro-organisms. Many of these microbial species are associated with specific mineral phases, and the interaction of mineral and microbial processes are of only recently recognized importance in several areas of hydrothermal research. Many submarine hydrothermal mineral phases form during… Show more

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Cited by 45 publications
(10 citation statements)
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“…C 2 O 4 2‐ + Ca 2+ = > CaC 2 O 4 · H 2 O, in dependence on pH of the environment with calcareous sediment usually deposited in shallow water near land, oxalate solubility, and diagenetic recrystallization . Comparison between Raman spectra of oxalate minerals present in natural patinas confirms that except the Cu‐oxalates and Na‐oxalates, a substantial band overlap is consistently reported for both Ca‐polymorphs (whewellite and weddellite), glushinskite and humboldtine, which together with spectral artifacts makes difficult discrimination between these components. In this context and due to Ca, Fe, Mg, and K detected in the patina, the admixture of other oxalate phases besides whewellite cannot be excluded.…”
Section: Resultssupporting
confidence: 54%
See 1 more Smart Citation
“…C 2 O 4 2‐ + Ca 2+ = > CaC 2 O 4 · H 2 O, in dependence on pH of the environment with calcareous sediment usually deposited in shallow water near land, oxalate solubility, and diagenetic recrystallization . Comparison between Raman spectra of oxalate minerals present in natural patinas confirms that except the Cu‐oxalates and Na‐oxalates, a substantial band overlap is consistently reported for both Ca‐polymorphs (whewellite and weddellite), glushinskite and humboldtine, which together with spectral artifacts makes difficult discrimination between these components. In this context and due to Ca, Fe, Mg, and K detected in the patina, the admixture of other oxalate phases besides whewellite cannot be excluded.…”
Section: Resultssupporting
confidence: 54%
“…This compound identified in the corrosion layer is also known as the major ore of copper, and its presence can be accompanied by other Cu compounds and secondary minerals depending on environmental conditions . It is also observed as a primary mineral in hydrothermal veins, which results from interaction mechanism between copper, the iron of the soil, and sulfur originating from decomposition of the organic matter in an almost oxygen‐free environment . In the case of ingots immersed together with iron bars for centuries in saline water, the presence of chalcopyrite resulting from a similar mechanism cannot be excluded.…”
Section: Resultsmentioning
confidence: 99%
“…Despite some modelling attempts of microbial reaction rates in submarine hydrothermal chimneys (LaRowe et al, 2014), there is still a lack of knowledge of the mineralogy of the new structures as well as the microbial turnover over time, especially if exposed to fluid flow. The interaction of mineral and microbial processes is of recognised importance (Breier et al, 2010). There are no previous studies available of this kind.…”
Section: Restore Sulphide Substrata (Restoration)mentioning
confidence: 99%
“…In a recent special issue of the Philosophical Transactions of the Royal Society, in a year that celebrated its 350th anniversary as the longest running scientific journal, several articles highlighted the role of Raman spectroscopy in the characterization of biosignatures of extremophilic colonization of geological substrates in a range of stressed terrestrial environments [25,30,[36][37][38][39][40][41][42][43][44][45]; these articles in the same issue which address the detection of geological and biogeological spectral markers that are relevant to space missions give a very good appreciation of the spectroscopic requirements that will be essential for the construction of a relevant spectral database [46] for the ExoMars and forthcoming space missions which have a Raman spectrometer aboard their rover vehicles. Some selected examples of the data which can be provided by the Raman spectroscopic interrogation of terrestrial Mars analogue sites will be highlighted.…”
Section: (A) Analytical Astrobiology Of Marsmentioning
confidence: 99%