Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-26T15:43:02.679Z Has data issue: false hasContentIssue false

Biogenic Saponite From an Active Submarine Hot Spring, Iceland

Published online by Cambridge University Press:  01 January 2024

A. Geptner
Affiliation:
Geological Institute, Russian Academy of Sciences, Pyzhevsky 7, 109017 Moscow, Russia
H. Kristmannsdóttir*
Affiliation:
University of Akureyri, Nordurslod, 600, Akureyri, Iceland
J. Kristjansson
Affiliation:
Prokaria, Gylfaflöt 5, 112 Reykjavik, Iceland
V. Marteinsson
Affiliation:
Prokaria, Gylfaflöt 5, 112 Reykjavik, Iceland
*
*E-mail address of corresponding author: hrefnaKr@mi.is
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

A study of the mineralogy, chemical composition and structure of poorly-crystalline saponite precipitated from a submarine hot spring in Eyjafjordur, northern Iceland is reported. Special emphasis was placed on the microstructures of the minerals and a possible connection with biological activity during their precipitation. The microstructures of the minerals were found to be very similar to specific clay minerals precipitated from geothermal vents in oceanic rift zones. The composition of the minerals was, however, found to be similar to magnesium silicate scales formed in geothermal installations in Iceland where geothermal waters were mixed with cold fresh waters. High contents of organic substances were found in the clay mineral samples as compared to geothermal precipitates from other localities. Microstructural features of the layer silicates in one of the samples suggest that a gelatinous substance was a precursor of the saponite clay. The organic matter content appears to be greater when the precipitates are more crystalline.

Type
Research Article
Copyright
Copyright © 2002, The Clay Minerals Society

References

Bjarnason, J., (1994) The speciation program Watch, version 2.1 Reykjavík Orkustofnun 7 pp.Google Scholar
Björnsson, A., (1981) Exploration of low-temperature geothermal fields for district heating in Akureyri, North Iceland Geothermal Resources Council Transactions 5 495 498.Google Scholar
Chafetz, H.S. and Folk, R.L., (1984) Travertines: depositional morphology and the bacterially-constructed constituents Journal of Sedimentary Petrology 45 289 319.Google Scholar
Drits, V.A. and Kossowskaya, A.G., (1990) Clay minerals: smectites. Mixed-layer silicates Geological Institute Transactions, 446 Moscow Nauka 214 pp.Google Scholar
Drits, V.A. Khvorova, I.V. Sokolova, A.L. and Voronin, B.I., (1989) Clay minerals in deep water hydrothermal structures of the Guayamas Depression (Gulf of California) Lithology and Mineral Resources 24 1015 (in Russian).Google Scholar
Eroshchev-Shak, V.A. Karpov, G.A. Lavrushin, V.Y.u. and Il’in, V.A., (1996) Bottom sediments from recent caldera thermal lakes in the Kamchatka Peninsula: Formation conditions and composition Lithology and Mineral Resources 31 174184 (in Russian).Google Scholar
Ferris, F.G. Beveridge, T.J. and Fyfe, W.S., (1986) Iron-silica crystallite nucleation by bacteria in a geothermal sediment Nature 320 609611 10.1038/320609a0.CrossRefGoogle Scholar
Folk, R.L., (1993) SEM imaging of bacteria and nannobacteria in carbonate sediments and rocks Journal of Sedimentary Petrology 63 990 999.Google Scholar
Folk, R.L. and Lynch, F.L., (1997) The possible role of nannobacteria (dwarf bacteria) clay-mineral diagenesis and the importance of careful sample preparation in high-magnification SEM study Journal of Sedimentary Research 67 583 589.Google Scholar
Geptner, A.R. Kristmannsdóttir, H. and Selezneva, M.A., (1987) Secondary minerals in basalts altered by hydro-thermal brines in Reykjanes Peninsula (Iceland) Lithology and Mineral Resources 22 2541 (in Russian).Google Scholar
Geptner, A.R., Petrova, V.V. and Kristmannsdóttir, H. (1995) On biochemical genesis of clay minerals in basalts, Iceland. Pp. 245247 in: WRI-8, Proceedings of the 8th International Symposium, Vladivostok, Russia.CrossRefGoogle Scholar
Geptner, A.R. Petrova, V.V. Sokolova, A.L. and Gor’kova, N.V., (1996) Biochemogenic formation of phyllosilicates during hydrothermal alteration of basalts in Iceland Lithology and Mineral Resources 32 249259 (in Russian).Google Scholar
Geptner, A.R. Alekseyeva, N.A. and Pikovsky, Y.u.I., (1999) Polycyclic aromatic hydrocarbons in volcanic rocks and hydrothermal minerals, Iceland Lithology and Mineral Resources 34 560580 (in Russian).Google Scholar
Gerasimenko, L.M. Goncharova, I.V. Zhegallo, E.A. Zavarzin, G.A. Zaitseva, L.V. Orleanskii, V.K. Rozanov, A.Y.u. and Ushatinskaya, G.T., (1996) Filamentous cyanobacteriae: The process of their mineralization (phosphatization) Lithology and Mineral Resources 31 185190 (in Russian).Google Scholar
Kohler, B. Singer, A. and Stoffers, P., (1994) Biogenic nontronite from Marine White smoker chimneys Clays and Clay Minerals 42 689701 10.1346/CCMN.1994.0420605.10.1346/CCMN.1994.0420605CrossRefGoogle Scholar
Kristmannsdóttir, H., Rona, P.A. Bostrom, K. Laubier, L. and Smith, K.L. Jr., (1984) Chemical evidence from Icelandic geothermal systems as compared to submarine geothermal systems Hydrothermal Processes at Seafloor Spreading Centers New York Plenum Publishing Corporation 291 320.Google Scholar
Kristmannsdóttir, H., (1989) Types of scaling occurring by geothermal utilization in Iceland Geothermics 18 183190 10.1016/0375-6505(89)90026-6.10.1016/0375-6505(89)90026-6CrossRefGoogle Scholar
Kristmannsdóttir, H. and Johnsen, S., (1982) Chemistry and stable isotope composition of geothermal waters in the Eyjafjordur region, northern Iceland Jokull 32 83 90.Google Scholar
Kristmannsdóttir, H. Ildefonse, P.h. Bertraux, J. Flank, A.M. and Armannsson, H., (1999) Crystal-chemistry of Mg-Si and Al-Si scales in geothermal waters, Iceland Geochemistry of the Earth’s Surface Rotterdam, The Netherlands Balkema 519 522.Google Scholar
Kristmannsdóttir, H., Hardardóttir, V. and Marteinsson, V.T. (2000) A study of water and heat exchangers in the swimming pool in Kopavogur. Orkustofnun, report HK-VH-VThM-2000/02, 15 pp (in Icelandic).Google Scholar
Lowenstam, H.A., (1981) Minerals formed by organisms Science 211 11261130 10.1126/science.7008198.CrossRefGoogle ScholarPubMed
Marteinsson, V.T. Birren, J.L. and Prieur, D., (1997) In situ enrichments and isolation of thermophilic microorganism from deep-sea vent environments Canadian Journal of Microbiology 43 694697 10.1139/m97-100.10.1139/m97-100CrossRefGoogle Scholar
Marteinsson, V.T. Kristjánsson, J.K. Kristmannsdóttir, H. Dahlkvist, M. Sömundsson, K. Hannington, M. Petursdóttir, S. Geptner, A. and Stoffers, S., (2000) Discovery and description of giant submarine smectite cones on the seafloor in Eyjafjordur, N. Iceland and a novel thermal microbial habitat Applied Environmental Microbiology 67 827833 10.1128/AEM.67.2.827-833.2001.CrossRefGoogle Scholar
Petersen, N. von Dobeneck, T. and Vali, H., (1986) Fossil bacterial magnetite in deep-sea sediments from the South Atlantic Ocean Nature 320 611615 10.1038/320611a0.10.1038/320611a0CrossRefGoogle Scholar
Sveinbjörnsdóttir, ÁE Arnorsson, S. Heinemeier, J. Boaretto, E., Arehart, G.B. and Hulston, J.R., (1998) Geochemistry of natural waters in Skagafjördur, N. Iceland. II. Isotopes WRI-9, Proceedings of the 9th International Symposium Rotterdam, The Netherlands Balkema.Google Scholar
Sverrisdóttir, G. Kristmannsdóttir, H. Olafsson, M., Kharaka, Y.K. and Maest, A.S., (1992) Magnesium silicate scales in geothermal utilization WRI-7, Proceedings of the 7th International Symposium Rotterdam, The Netherlands Balkema 1431 1434.Google Scholar
Tazaki, K., (1997) Biomineralization of layer silicates and hydrated Fe/Mn oxides in microbial mats: an electron microscopical study Clays and Clay Minerals 45 203212 10.1346/CCMN.1997.0450208.CrossRefGoogle Scholar
Turekian, K.K. and Wedepohl, K.H., (1969) The oceans, streams and atmosphere Handbook of Geochemistry New York Springer 297323 10.1007/978-3-642-46300-6_10.CrossRefGoogle Scholar