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Palaeoenvironmental significance of lacustrine stromatolite forms from the Middle Old Red Sandstone of the Orcadian Basin

Published online by Cambridge University Press:  19 July 2013

S. D. ANDREWS  and
N. H. TREWIN
S. D. ANDREWS*
Affiliation:
Department of Geology and Petroleum Geology, University of Aberdeen, King's College, Aberdeen, AB24 3UE, United Kingdom CASP, University of Cambridge, 181a Huntingdon Road, Cambridge, CB3 ODH, United Kingdom
N. H. TREWIN
Affiliation:
Department of Geology and Petroleum Geology, University of Aberdeen, King's College, Aberdeen, AB24 3UE, United Kingdom
*
Author for correspondence: steven.andrews@abdn.ac.uk
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Abstract

The form of microbialite accumulations is largely the product of environmental processes and microbial activity. Recent work has largely concentrated on the identification and classification of microbialites with little attention being paid to their environmental significance. This study describes the environmental distribution of the varied stromatolite forms recorded from the Middle Old Red Sandstone sequences of the Orcadian Basin. Comparisons are made with Triassic examples from East Greenland and modern microbialite accumulations. The Middle Old Red Sandstone of Northern Scotland was deposited in a predominantly lacustrine setting. Stromatolites are recorded from both steep basin margin coincident settings and lower gradient settings where the lake margin was distant from the basin margin. In the latter case stromatolite development is largely restricted to transgressive lacustrine sequences, during the deposition of which reduced rates of sedimentation resulted from the migration of sediment input points towards the basin margin. Stromatolite sheets, domal mounds, aligned mounds (and associated runnels), sand-cored stromatolite mounds and reefal stromatolite accumulations have been identified representing the transition from more sheltered to more exposed environments. In basin margin coincident settings stromatolite accumulation is restricted to areas of low sedimentation where microbialites coat boulders and pebbles. A model for the palaeoenvironmental distribution of the stromatolite forms described is proposed and is shown to be applicable to similar examples from the Triassic of East Greenland. It is suggested that this model may be more widely applicable to stromatolitic accumulations in similar lacustrine settings through large portions of the Phanerozoic.

Keywords

microbialiteslacustrineMiddle Old Red SandstoneOrcadian BasinNorthern Scotland
Type
Original Articles
Information
Geological Magazine , Volume 151 , Issue 3 , May 2014 , pp. 414 - 429
Copyright
Copyright © Cambridge University Press 2013 

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References

Aitken, J. D. 1967. Classification and environmental significance of cryptalgal limestones and dolomites, with illustrations from the Cambrian and Ordovician of southwestern Alberta. Journal of Sedimentary Petrology 37, 1163–78.Google Scholar
Allwood, A. C., Walter, M. R., Burch, I. W. & Kamber, B. S. 2007. 3.43 billion-year-old stromatolite reef from the Pilbara Craton of Western Australia: ecosystem-scale insights to early life on Earth. Precambrian Research 158, 198227.CrossRefGoogle Scholar
Andres, M. S. & Reid, R. P. 2006. Growth morphologies of modem marine stromatolites: a case study from Highborne Cay, Bahamas. Sedimentary Geology 185, 319–28.CrossRefGoogle Scholar
Andrews, S. D. & Trewin, N. H. 2010. Periodicity determination of lacustrine cycles from the Devonian of Northern Scotland. Scottish Journal of Geology 46, 143–55.Google Scholar
Braga, J. C., Martin, J. M. & Riding, R. 1995. Controls on microbial dome fabric development along a carbonate-siliciclastic shelf-basin transect, Miocene, SE Spain. Palaios 10, 347–61.Google Scholar
Carozzi, A. V. 1962. Observations on algal biostromes in the Great Salt Lake, Utah. Journal of Geology 70, 246–52.Google Scholar
Clemmensen, L. B. 1978. Lacustrine facies and stromatolites from Middle Triassic of East Greenland. Journal of Sedimentary Petrology 48, 1111–27.Google Scholar
Davies, G. R. 1970. Algal laminated sediments, Gladstone Embayment, Shark Bay, Western Australia. In Carbonate Sedimentation and Environments, Shark Bay, Western Australia (eds Logan, B. W., Davies, G. R., Read, J. F. & Cebulski, D. E.), pp. 169205. American Association of Petroleum Geologists Memoir 13.Google Scholar
Donovan, R. N. 1973. Basin margin deposits of the Middle Old Red Sandstone at Dirlot, Caithness. Scottish Journal of Geology 9, 203–11.Google Scholar
Donovan, R. N. 1975. Devonian lacustrine limestones at the margin of the Orcadian Basin, Scotland. Journal of the Geological Society, London 131, 489510.Google Scholar
Duncan, A. D. & Hamilton, R. F. M. 1988. Palaeolimnology and organic geochemistry of the Middle Devonian in the Orcadian Basin. In Lacustrine Petroleum Source Rocks (eds Fleet, A. J., Kelts, K. & Talbot, M. R.), pp. 173201. Geological Society of London, Special Publication no. 40.Google Scholar
Eckman, J. E., Andres, M. S., Marinelli, R. L., Bowlin, E., Reid, R. P., Aspden, R. J. & Paterson, D. M. 2008. Wave and sediment dynamics along a shallow subtidal sandy beach inhabited by modern stromatolites. Geobiology 6, 2132.CrossRefGoogle Scholar
Fannin, N. G. T. 1969. Stromatolites from the Middle Old Red Sandstone of Western Orkney. Geological Magazine 106, 7788.Google Scholar
Gischler, E., Gibson, M. A. & Oschmann, W. 2008. Giant Holocene freshwater microbialites, Laguna Bacalar, Quintana Roo, Mexico. Sedimentology 55, 1293–309.CrossRefGoogle Scholar
Heddle, M. F. 1880. The geognosy and mineralogy of Scotland. Mineralogical Magazine 3, 147–77.CrossRefGoogle Scholar
Hoffman, P. F. 1976. Environmental diversity of Middle Precambrian stromatolites. In Stromatolites (ed. Walter, M. R.), pp. 566611. Amsterdam: Elsevier.Google Scholar
Janaway, T. M. & Parnell, J. 1989. Carbonate production within the Orcadian Basin, Northern Scotland: a petrographic and geochemical study. Palaeogeography, Palaeoclimatology, Palaeoecology 70, 89105.Google Scholar
Kazmierczak, J. & Kempe, S. 2006. Genuine modern analogues of Precambrian stromatolites from caldera lakes of Niuafo’ou Island, Tonga. Naturwissenschaften 93, 119–26.Google Scholar
Kent, D. V. & Clemmensen, L. B. 1996. Paleomagnetism and cycle stratigraphy of the Triassic Fleming Fjord and Gipsdalen Formations of East Greenland. Bulletin of the Geological Society of Denmark 42, 121–36.Google Scholar
Logan, B. W. 1981. Algal mats, cryptalgal fabrics and structures (supplement 2). In Modern Carbonate and Evaporite Sediments of Shark Bay and Lake Macleod, Western Australia. Perth: Geological Society of Australia, Australian Geological Convention, Field Excursion Guide Book.Google Scholar
Logan, B. W., Rezak, R. & Ginsburg, R. N. 1964. Classification and environmental significance of algal stromatolites. Journal of Geology 72, 6883.CrossRefGoogle Scholar
Martin, J. M., Braga, J. C. & Riding, R. 1993. Siliciclastic stromatolites and thrombolites, Late Miocene, SE Spain. Journal of Sedimentary Petrology 63, 131–9.Google Scholar
Moore, L., Knott, B. & Stanley, N. 1984. The stromatolites of Lake Clifton, Western Australia. Search 14, 309–14.Google Scholar
Parnell, J. & Janaway, T. M. 1990. Sulphide-mineralised algal breccias in a Devonian evaporitic lake system, Orkney, Scotland. Ore Geology Reviews 5, 445–60.Google Scholar
Parnell, J., Marshall, J. E. A. & Astin, T. R. 1990. Field guide to lacustrine deposits of the Orcadian Basin, Scotland. In 13th International Sedimentological Congress, Nottingham. British Sedimentological Research Group.Google Scholar
Paul, J. & Peryt, T. M. 2000. Kalkowsky's stromatolites revisited (Lower Triassic Buntsandstein, Harz Mountains, Germany). Palaeogeography Palaeoclimatology Palaeoecology 161, 435–58.Google Scholar
Playford, P. E. 1980. Environmental controls on the morphology of modern stromatolites at Hamelin Pool, Western Australia. Western Australia Geological Survey Annual Report (for 1979), 73–7.Google Scholar
Reid, R. P., James, N. P., Macintyre, I. G., Dupraz, C. P. & Burne, R. V. 2003. Shark Bay stromatolites: microfabrics and reinterpretation of origins. Facies 49, 299324.Google Scholar
Riding, R. 2000. Microbial carbonates: the geological record of calcified bacterial-algal mats and biofilms. Sedimentology 47, 179214.CrossRefGoogle Scholar
Riding, R. 2011. Microbialites, stromatolites, and thrombolites. In Encyclopedia of Geobiology (eds Reitner, J. & Thiel, V.), pp. 635–54. Encyclopedia of Earth Science Series. Heidelberg: Springer.CrossRefGoogle Scholar
Schieber, J. 1998. Possible indicators of microbial mat deposits in shales and sandstones: examples from the Mid-Proterozoic Belt Supergroup, Montana, USA. Sedimentary Geology 120, 105–24.Google Scholar
Schröder, S., Beukes, N. J. & Sumner, D. Y. 2009. Microbialite-sediment interactions on the slope of the Campbellrand carbonate platform (Neoarchean, South Africa). Precambrian Research 169, 6879.Google Scholar
Trewin, N. H. & Thirlwall, M. F. 2002. Old Red Sandstone. In The Geology of Scotland (ed. Trewin, N. H.), pp. 213–49. London: The Geological Society.Google Scholar
Trompette, R. 1982. Upper Proterozoic (1800–570 Ma) stratigraphy – a survey of lithostratigraphic, paleontological, radiochronological and magnetic correlations. Precambrian Research 18, 2752.Google Scholar