Burgsvik Beds

Summary

The Burgsvik Beds are a sequence of shallow marine limestones and sandstones found near the locality of Burgsvik in the southern part of Gotland, Sweden. The beds were deposited in the Upper Silurian period, around 420 million years ago, in warm, equatorial waters frequently ravaged by storms, in front of an advancing shoreline. The Burgsvik Formation comprises two members, the Burgsvik Sandstone and the Burgsvik Oolite.[1]

Burgsvik Beds
Stratigraphic range: Ludfordian
~420 Ma
Outcrop map of the Burgsvik Beds (blue)
TypeGeological formation
UnderliesBurgsvik Oolite
OverliesEke Formation
Lithology
PrimaryLimestone, sandstone, mudstone
Location
Coordinates57°02′13″N 18°17′03″E / 57.036990°N 18.284230°E / 57.036990; 18.284230
RegionSouth Gotland
Country Sweden
Type section
Named forBurgsvik

Appearance edit

The beds consists of thin to very thick layers of a light grey, fine grained argillaceous sandstone, containing a small calcareous element. The sandstones are occasionally intercalated with very thin-bedded blue-grey claystone. In places, the sandstone is overlain by the upper Burgsvik beds, which comprise thin-bedded, light-to-bluish grey, oolitic limestone with alternating sandy beds containing problematic structures described by Manten (1966).

Depositional environment edit

Manten (1966) deduces that the Burgsvik beds were formed fairly close to the shoreline on a beach "faintly sloping towards the open sea", and that they were extensively reworked by the action of tides and storms. Evidence from cross-bedding and ripple marks is taken to imply a subaquaeous origin; rounded oolite pebbles and slightly rounded, size-sorted fossils are evidence of a high-energy environment. The presence of certain species of lamellibranch molluscs suggest a marine setting, and the thick shells present are also indicative of that type of environment. Rare burrows, sometimes found in clay lenses, may have formed in quieter waters that were protected by low sand or reef barriers from wave action. Features that only form on sub-aerial ground, including erosion channels, pothole-like excavations, mud cracks and dendritic rill marks are all present, and provide firm evidence that parts of the environment consisted of beaches or unvegetated ground that occasionally ran dry. Detailed petrographic and paleæoecological analysis of the upper and top few metres of the middle Burgsvik Beds by Stel and de Coo (1977) confirm that this section of the sequence was deposited between the beach and the lower foreshore; oolites and oncolites in the upper strata form in an "agitated shallow marine setting", implying a minor tidal influence. The paleoshoreline was located to the northeast, and facies become progressively more marine in character progressing to the southwest (Jeppsson 2005).

Recent studies suggest that the sandstone might in fact represent delta deposits.[2]

Palaeogeographic reconstructions allow the position of Gotland at the time of deposition to be deduced, and it appears that the Burgsvik beds were deposited near the equator (Torsvik et al. 1993). Combined with the high temperatures of the Silurian, this may have led to very hot, hypersaline waters.[citation needed]

Sedimentology edit

Long (1993) recognises three lithofacies in the Burgsvik beds; a poorly exposed silty/sandy mudstone facies dominant in the lower beds, appearing as interbeds in the middle beds; a fine to very fine sandstone; and a "biofacies" consisting of ooids, oncolites and bioclasts. He challenges three interpretations of the sub-aerial sandstone facies. Contrary to Gray et al.'s (1974) tidal mud flat interpretation, Long surmises that it may represent locally emergent offshore bars, near-shore sands or beach deposits. Tides cannot be a dominant factor, as cross-stratification is abundant; storm beds, recognised by hummocky cross-stratification, are also common, suggesting that storms were important in shaping the landscape. Irregularly aligned prod and scour marks on the sea floor shows that waves also played a role. The most favourable conclusion appears to be that the facies represents a shoaling sequence — the migration of sand wave complexes, detached offshore bars (Swift & Field 1981, Brenner et al. 1985) or isolated mid-shelf bars (La Fon 1981).

Correlation edit

Mainly due to the inhomogeneous nature of shoreline deposits, lateral variation is intense throughout the Burgsvik beds, making correlation difficult (Laufeld 1974). However, using freshly available borehole data, Manten (1971) was able to further sub-divide the Burgsvik beds into 3 members, illustrated above. The upper bed can be recognised across the entire outcrop belt, varying slightly along strike, and has a distinctive lower contact. The lower bed, however, is easily eroded and rarely exposed. To further complicate the matter, the depositional area was being continually provided with sediment — and thus filling up — from the north west. As bioherm detritus and terrigenous infill accumulated, the coast prograded, and the reef zone advanced in front of it to the south west. This pattern is complicated further by sea level changes, making precise interpretation troublesome (Laufeld 1974).

Correlation to units elsewhere in the world is aided by the high-resolution conodont data available; the beds are in the Ozarkodina snajdri conodont subdivision of the Pseudomonoclimacis latilobus graptolite zone, which is also well displayed in, for example, Estonia (Jeppsson et al. 1994, Jeppsson & Männik 1993).

Paleontological interest edit

 
This wrinkled "elephant skin" texture is a trace fossil of a non-stromatolite microbial mat. The image shows the location, in the Burgsvik beds, where the texture was first identified as evidence of a microbial mat.[3]

As well as reef-building organisms and the thick-shelled Lamellibranchia mentioned above, the Burgsvik beds are also of interest to micropalæontologists. Their quiet tectonic history — with the depth of burial never exceeding 200 metres (660 ft) and "no thermal maturation" occurring (Jeppsson 1983) — means that organic material is preserved relatively unscathed, to a degree of quality barely rivalled anywhere else on earth for rocks of this age - indeed, the preservation is equivalent to that expected from the Tertiary (Sherwood-Pike and Gray 1985). Dissolution of the rocks in hydrofluoric acid leaves the organic matter unscathed, and putative fungi (Ornatifilum) and fæcal pellets have been unearthed (Sherwood-Pike and Gray 1985), as well as supposed euglenids (Gray and Boucot 1989): the latter being of particular interest as not one other fossil euglenid is known. A lack of marine macrofossils in plant-rich beds suggests that large grazers or predators may have been absent, perhaps because water depths were so shallow - this may have aided fossil preservation (Gray et al. 1974).

The beds are the first location where it was recognized that "elephant skin" wrinkles in marine sediments are trace fossils of microbial mats,[3] which were Earth's most sophisticated form of life for nearly 2 billion years and are still the major factors maintaining life on Earth.[4]

Association with mass extinction edit

Martma et al. (2005) assign a Mid-Ludfordian (Upper Ludlow) age to the Burgsvik, which places the beds in close temporal proximity to the Lau event, a late Silurian mass extinction. They also note a positive δ13Corg excursion in the Burgsvik and underlying Eke beds. Such excursions are normally associated with the decrease in oceanic productivity caused by mass extinctions. This could also be interpreted as climate, mainly precipitation, controlling the distribution of facies; high δ13C is often observed in deposits formed in arid conditions.

Calner (2005) notes that anachronistic facies are observed in other strata spanning the Lau event, places the Burgsvik beds immediately after this mass extinction (Calner 2005b), noting the occurrence of flat-pebble conglomerates in the underlying Eke beds.

Correlation with the P-S episodes postulated by Jeppsson (1990) suggests that the beds were deposited during a wet period - a P episode.

See also edit

References edit

  1. ^ Calner, Mikael; Eriksson, Mårten J. (2006). "Evidence for rapid environmental changes in low latitudes during the Late Silurian Lau Event: the Burgen-1 drillcore, Gotland, Sweden". Geological Magazine. 143 (1): 15. Bibcode:2006GeoM..143...15C. doi:10.1017/S001675680500169X. S2CID 129946754.
  2. ^ Eriksson, M. J.; Calner, M. (2008). "A sequence stratigraphical model for the Late Ludfordian (Silurian) of Gotland, Sweden: implications for timing between changes in sea level, palaeoecology, and the global carbon cycle". Facies. 54 (2): 253–276. doi:10.1007/s10347-007-0128-y. S2CID 128406414.
  3. ^ a b Manten, A. (1966). "Some problematic shallow-marine structures". Marine Geology. 4 (3): 227–669. Bibcode:1966MGeol...4..227M. doi:10.1016/0025-3227(66)90023-5. hdl:1874/16526. S2CID 129854399.
  4. ^ Krumbein, W.E.; Brehm, U.; Gerdes, G.; Gorbushina, A.A.; Levit, G. & Palinska, K.A. (2003). "Biofilm, Biodictyon, Biomat Microbialites, Oolites, Stromatolites, Geophysiology, Global Mechanism, Parahistology". In Krumbein, W.E.; Paterson, D.M. & Zavarzin, G.A. (eds.). Fossil and Recent Biofilms: A Natural History of Life on Earth (PDF). Kluwer Academic. pp. 1–28. ISBN 978-1-4020-1597-7. Archived from the original (PDF) on 2007-01-06. Retrieved 2008-07-09.

Bibliography edit

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