Receptaculites

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Receptaculites
Temporal range: 488–250  Ma
Receptaculitid.JPG
Receptaculitid from the Ordovician of Estonia.
Scientific classification OOjs UI icon edit-ltr.svg
(unranked): Viridiplantae
Division: Chlorophyta
Class: Ulvophyceae
Order: Dasycladales (?)
Family: Receptaculitaceae
Genus: Receptaculites
Defrance 1827
Species [1]
  • R. arcticusEtheridge [2]
  • R. biconstrictusE.O.Ulrich [2]
  • R. maeandriformisA.N.Ivanov [2]
  • R. monticulatus
  • R. neptuniDefrance [2]
  • R. occidentalis

Receptaculites is the name-bearing genus for an extinct group of conspicuous benthic marine genera, the receptaculitids (formally Receptaculitaceae or Receptaculitidae), that lived from the Early Ordovician through the Permian period, peaking in the Middle Ordovician. The group's phylogenetic origin has long been obscure, with some arguing that they were calcareous algae, probably of the order Dasycladales. [3] Receptaculitids lived in warm, shallow seas, [3] but consensus disagreeing. [4] [5] They have been described from all continents except Antarctica. [6] [2] In some areas they were important reef-formers, and they also occur as isolated specimens. [7]

Receptaculitid from the Kimmswick Limestone (Middle Ordovician) near Ozora, Missouri. KimmswickOzoraMidOrdReceptaculitid.jpg
Receptaculitid from the Kimmswick Limestone (Middle Ordovician) near Ozora, Missouri.
Receptaculites oweni, late Ordovician, Red River Formation, Garson, Manitoba. Receptaculites oweni.jpg
Receptaculites oweni, late Ordovician, Red River Formation, Garson, Manitoba.

Receptaculites and its relatives have a double-spiral, radiating pattern of rhombus-shaped plates supported by spindle-like objects called meroms. [8] Fossils can usually be identified by the intersecting patterns of clockwise and counterclockwise rows of plates or stalk spaces, superficially similar to the arrangement of disk florets on a sunflower—hence the common name "sunflower coral" (sic). [9]

Receptaculitids have sometimes been compared to the morphologically similar, but probably distantly related, cyclocrinitids. [10] [11]

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<span class="mw-page-title-main">Ulvophyceae</span> Class of green algae

The Ulvophyceae or ulvophytes are a class of green algae, distinguished mainly on the basis of ultrastructural morphology, life cycle and molecular phylogenetic data. The sea lettuce, Ulva, belongs here. Other well-known members include Caulerpa, Codium, Acetabularia, Cladophora, Trentepohlia and Monostroma.

<span class="mw-page-title-main">Coralline algae</span> Order of algae (Corallinales)

Coralline algae are red algae in the order Corallinales. They are characterized by a thallus that is hard because of calcareous deposits contained within the cell walls. The colors of these algae are most typically pink, or some other shade of red, but some species can be purple, yellow, blue, white, or gray-green. Coralline algae play an important role in the ecology of coral reefs. Sea urchins, parrot fish, and limpets and chitons feed on coralline algae. In the temperate Mediterranean Sea, coralline algae are the main builders of a typical algal reef, the Coralligène ("coralligenous"). Many are typically encrusting and rock-like, found in marine waters all over the world. Only one species lives in freshwater. Unattached specimens may form relatively smooth compact balls to warty or fruticose thalli.

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Sphaerocodium is a fossil that represents the remains of bacteria in the phylum Cyanobacteria, often called blue-green algae.

Proaulopora is a Cambrian–Ordovician fossil genus of calcareous algae. It has been variously thought to belong to the green algae, red algae or cyanobacteria. It was originally established by the Russian paleontologist Aleksandr Grigoryevich Vologdin in 1937, for species known from the Lower Cambrian of the western Altai Mountains.

<span class="mw-page-title-main">Winneshiek Shale</span>

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Cyclocrinitids are an early (mid-Ordovician–early-Silurian) Dasycladalean algae, resembling but probably not closely related to the Receptaculitids.

References

  1. "Family: Receptaculitidae". The Paleobiology Database. Retrieved 2011-08-15.
  2. 1 2 3 4 5 Guiry, M.D.; Guiry, G.M. "Receptaculites". AlgaeBase . World-wide electronic publication, National University of Ireland, Galway. Retrieved 2022-02-28.
  3. 1 2 Byrnes, J.G. 1968. Notes on the nature and environmental significance of the Receptaculitaceae. Lethaia, vol. 1, p. 368-381.
  4. Beadle, S. C. (1991). "Cyclocrinitids". Calcareous Algae and Stromatolites. pp. 114–124. doi:10.1007/978-3-642-52335-9_6. ISBN   978-3-642-52337-3.
  5. Nitecki, Matthew H.; Webby, Barry D.; Spjeldnaes, Nils; Yong-Yi, Zhen (2004). "31. Receptaculitids and Algae". The Great Ordovician Biodiversification Event. pp. 336–347. doi:10.7312/webb12678-032. ISBN   9780231126786.
  6. Rietschel, S. and Nitecki, M.H. 1984. Ordovician Receptaculitid algae from Burma. Palaeontology, vol. 27, p. 415-420.
  7. Pratt, B.R. and Weissenberger, J., 1988. Fore-slope Receptaculitid mounds from the Frasnian of the Rocky Mountains, Alberta. In: Reefs: Canada and adjacent areas, Canadian Society of Petroleum Geologists Memoir 13, p. 510-513.
  8. Wilson, Mark (2017-02-10). "Wooster's Fossil of the Week: A receptaculitid (Middle Ordovician of Missouri)" . Retrieved 2021-05-19.
  9. Stinchcomb, Bruce L. (November 1997). "Missouri Fossils". Rocks & Minerals. 72 (6): 393–399. doi:10.1080/00357529709605072.
  10. Nitecki, Matthew H.; Webby, Barry D.; Spjeldnaes, Nils; Yong-Yi, Zhen (31 December 2004). "31. Receptaculitids and Algae". The Great Ordovician Biodiversification Event: 336–347. doi:10.7312/webb12678-032. ISBN   9780231126786.
  11. Beadle, Steven C. (January 1988). "Dasyclads, cyclocrinitids and receptaculitids: comparative morphology and paleoecology". Lethaia. 21 (1): 1–12. doi:10.1111/j.1502-3931.1988.tb01745.x.
Receptaculitid in Ordovician Tyndall limestone from Manitoba, Canada. Tyndal Stone with fossil.jpg
Receptaculitid in Ordovician Tyndall limestone from Manitoba, Canada.
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