Diplocraterion

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Diplocraterion
Tuscarora Formation Diplocraterion.jpg
Diplocraterion burrow (at left) from the Silurian-age Tuscarora Formation at Bald Eagle Mountain, Centre County, Pennsylvania. Specimen is ~22cm high.
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Ichnogenus: Diplocraterion
Sketch by Richter (1926) showing spreite in a Diplocraterion parallelum burrow. Diplocraterion parallelum - Richter1926.gif
Sketch by Richter (1926) showing spreite in a Diplocraterion parallelum burrow.

Diplocraterion is an ichnogenus describing vertical U-shaped burrows having a spreite (weblike construction) between the two limbs of the U. [1] [2] The spreite of an individual Diplocraterion trace can be either protrusive (between the paired tubes) or retrusive (below the paired tubes). [3] Some ichnospecies have both types (e.g., Diplocraterion yoyo). [4] The presence/absence of funnel-shaped openings should not be used as an ichnotaxobase due to the high probability that the upper portions of the trace may have been eroded away. [2] Observation of the orientation of Diplocraterion in the field is frequently used to determine the way up of rock strata at outcrop. [5]

Contents

There are several ichnospecies of Diplocraterion.

Some Ichnospecies of Diplocraterion
IchnospeciesDiagnosis
D. parallelum [6] Parallel burrow walls and unidirectional spreite [6] [2]
D. helmerseni [7] U-tubes expand laterally at the base [7] [2]
D. biclavatum [8] Arms of the U-tube extend below the curved base and form blind pouches [8] [2]
D. habichi [9] Arms of the U-tube diverge upward [9] [2]
D. polyupsilon [10] Bidirectional spreite that constrict upward [10] [2]
D. yoyo [4] U-tubes with both retrusive and protrusive spreiten [4]

Ethology

The various ichnospecies of Diplocraterion provide a good example of how ethology (animal-substrate interactions and behavior) can be interpreted from trace fossils. Diplocraterion is a classic example of equilibrichnia (equilibrium traces). [4] [11] These types of traces represent gradual adjustments to background sedimentation and erosion rates and reflect the efforts of the organisms to maintain a specific depth within the substrate. [11] This movement within the substrate produces the two types of spreite (protrusive and retrusive) characteristic of Diplocraterion and other ichnotaxa (e.g., Rhizocorallium ). [3] [11]

Most Diplocraterion show only protrusive spreit (e.g., D. parallelum, D. polyupsilon, D. biclavatum). [6] [10] [8] These indicate that the trace was produced under predominantly erosive conditions where the organism was constantly burrowing deeper into the substrate as sediment was eroded from the top. [4] D. yoyo has both protrusive and retrusive spreiten indicating highly variable conditions (erosional and depositional) leading to the need for the organisms to constantly adjust itself up and down within the substrate to maintain equilibrium and not become exposed or buried. [4]

See also

Related Research Articles

<span class="mw-page-title-main">Trace fossil</span> Geological record of biological activity

A trace fossil, also known as an ichnofossil, is a fossil record of biological activity by lifeforms but not the preserved remains of the organism itself. Trace fossils contrast with body fossils, which are the fossilized remains of parts of organisms' bodies, usually altered by later chemical activity or mineralization. The study of such trace fossils is ichnology and is the work of ichnologists.

<span class="mw-page-title-main">Bioerosion</span> Erosion of hard substrates by living organisms

Bioerosion describes the breakdown of hard ocean substrates – and less often terrestrial substrates – by living organisms. Marine bioerosion can be caused by mollusks, polychaete worms, phoronids, sponges, crustaceans, echinoids, and fish; it can occur on coastlines, on coral reefs, and on ships; its mechanisms include biotic boring, drilling, rasping, and scraping. On dry land, bioerosion is typically performed by pioneer plants or plant-like organisms such as lichen, and mostly chemical or mechanical in nature.

<span class="mw-page-title-main">Burrow</span> Underground animal home dug in soft dirt

A burrow is a hole or tunnel excavated into the ground by an animal to construct a space suitable for habitation or temporary refuge, or as a byproduct of locomotion. Burrows provide a form of shelter against predation and exposure to the elements, and can be found in nearly every biome and among various biological interactions. Many animal species are known to form burrows. These species range from small amphipods, to very large vertebrate species such as the polar bear. Burrows can be constructed into a wide variety of substrates and can range in complexity from a simple tube a few centimeters long to a complex network of interconnecting tunnels and chambers hundreds or thousands of meters in total length; an example of the latter level of complexity, a well-developed burrow, would be a rabbit warren.

Trace fossils are classified in various ways for different purposes. Traces can be classified taxonomically, ethologically, and toponomically, that is, according to their relationship to the surrounding sedimentary layers. Except in the rare cases where the original maker of a trace fossil can be identified with confidence, phylogenetic classification of trace fossils is an unreasonable proposition.

<i>Zoophycos</i> Trace fossil

Zoophycos is a somewhat cosmopolitan ichnogenus thought to be produced by moving and feeding polychaete worms.

<i>Paleodictyon</i> Trace fossil

Paleodictyon is a trace fossil, usually interpreted to be a burrow, which appears in the geologic marine record beginning in the Precambrian/Early Cambrian and in modern ocean environments. Paleodictyon were first described by Giuseppe Meneghini in 1850. The origin of the trace fossil is enigmatic and numerous candidates have been proposed.

<span class="mw-page-title-main">Sedimentary structures</span> Geologic structures formed during sediment deposition

Sedimentary structures include all kinds of features in sediments and sedimentary rocks, formed at the time of deposition.

<i>Skolithos</i> Trace fossil

Skolithos is a common trace fossil ichnogenus that is, or was originally, an approximately vertical cylindrical burrow with a distinct lining. It was produced globally by a variety of organisms, mostly in shallow marine environments, and appears as linear features in sedimentary rocks.

<i>Rhizocorallium</i> Trace fossil

Rhizocorallium is an ichnogenus of burrow, the inclination of which is typically within 10° of the bedding planes of the sediment. These burrows can be very large, over a meter long in sediments that show good preservation, e.g. Jurassic rocks of the Yorkshire Coast, but the width is usually only up to 2 cm, restricted by the size of the organisms producing it. It is thought that they represent fodinichnia as the animal scoured the sediment for food.

<span class="mw-page-title-main">Ichnofacies</span> Trace fossil

An ichnofacies is an assemblage of trace fossils that provides an indication of the conditions that their formative organisms inhabited.

<span class="mw-page-title-main">Cambrian substrate revolution</span> Diversification of animal burrowing

The "Cambrian substrate revolution" or "Agronomic revolution", evidenced in trace fossils, is a sudden diversification of animal burrowing during the early Cambrian period.

<span class="mw-page-title-main">Microbial mat</span> Multi-layered sheet of microorganisms

A microbial mat is a multi-layered sheet of microorganisms, mainly bacteria and archaea, or bacteria alone. Microbial mats grow at interfaces between different types of material, mostly on submerged or moist surfaces, but a few survive in deserts. A few are found as endosymbionts of animals.

<span class="mw-page-title-main">Coastal biogeomorphology</span>

Since the 1990s, biogeomorphology has developed as an established research field examining the interrelationship between organisms and geomorphic processes in a variety of environments, both marine, and terrestrial. Coastal biogeomorphology looks at the interaction between marine organisms and coastal geomorphic processes. Biogeomorphology is a subdiscipline of geomorphology.

<i>Ophiomorpha</i> Trace fossil

Ophiomorpha is an ichnotaxon, usually interpreted as a burrow of an organism living in the near-shore environment. The burrow lining is more or less smooth on the inside, and densely to strongly mammalated or nodose on the outside, due to the packing of nodules for support of the burrow. Branching is irregular but Y-shaped where present. It is often considered part of the Skolithos ichnofacies, where it has occurred since the early Permian, though it has also occurred in deep water settings since the Late Jurassic, such as well-oxygenated turbidites.

Conostichus is an ichnogenus of cnidarian trace fossil. They are nowadays considered to represent a burrow structure serving as a holdfast for an anemone-like organism.

<i>Helminthopsis</i> Trace fossil

Helminthopsis is the ichnogenus of a type of trace fossil that is found preserved on the bedding planes of fine-grained sedimentary rocks. It is characterized by short, curvilinear, non-branching, parallel-sided, unlined traces on bedding surfaces. It is thought to represent the submarine feeding trails of an invertebrate organism that worked the surface of muddy substrates in search of food. Because Helminthopsis traces never cross over themselves, the ichnogenus is distinguished from similar traces assigned to the Gordia ichnogenus. The similar sounding, but now obsolete, ichnogenus Helminthoida refers to a somewhat similar trace characterized by regular, back-and-forth meanders, whereas Helminthopsis traces are irregular.

<i>Chondrites</i> (genus) Trace fossil

Chondrites is a trace fossil ichnogenus, preserved as small branching burrows of the same diameter that superficially resemble the roots of a plant. The origin of these structures is currently unknown. Chondrites is found in marine sediments from the Cambrian period of the Paleozoic onwards. It is especially common in sediments that were deposited in reduced-oxygen environments.

<i>Nereites</i> Trace fossil

Nereites is an ichnogenus of trace fossil. Modern tracemakers of incipient Nereites include worm-like organisms, horseshoe crabs and hermit crabs. Traditionally, two models have been proposed for Nereites:

  1. in the ‘worm model’, Nereites is a feeding burrow produced by wormlike organisms, probing and backfilling laterally
  2. in the ‘arthropod model’, the characteristic lobes are pressure-release structures made by arthropod legs. According to this interpretation, Nereites is a locomotion trail
<span class="mw-page-title-main">Spreite</span>

Spreite, meaning leaf-blade in German is a stacked, curved, layered structure that is characteristic of certain trace fossils. They are formed by invertebrate organisms tunneling back and forth through sediment in search of food. The organism moves perpendicularly just enough at the start of each back-and-forth pass so that it avoids reworking a previously tunneled area, thereby ensuring that it only makes feeding passes through fresh, unworked sediment.

<i>Muensteria</i> Trace fossil

Muensteria is the ichnogenus of a type of trace fossil that is found in sedimentary rocks, and is thought to represent the horizontal burrow of a marine invertebrate organism. It is a horizontal, non-branching, unlined, tube-like burrow characterized by menisci, which are concave to flat laminae within the burrow created as the organism packs sediment and fecal material behind it when moving forward in the burrow. Muensteria is one example of a meniscate burrow.

References

  1. Richter, Rudolf (1926). "Flachseebeobachtungen zur Paläontologie und Geologie. XII-XIV". Senckenbergiana. 8: 200–224.
  2. 1 2 3 4 5 6 7 Fursich, F.T. (1974). "On Diplocraterion Torell 1870 and the significance of morphological features in vertical, spreiten-bearing, U-shaped trace fossils". Journal of Paleontology. 48 (5): 952–962. JSTOR   1303293.
  3. 1 2 Cornish, F.G. (1986). "The Trace-Fossil Diplocraterion: Evidence of Animal-Sediment Interactions in Cambrian Tidal Deposits". PALAIOS. 1 (5): 478–491. Bibcode:1986Palai...1..478C. doi:10.2307/3514630. JSTOR   3514630.
  4. 1 2 3 4 5 6 Goldring, Roland (1962). "The trace fossils of the Baggy Beds (Upper Devonian) of North Devon, England". Paläontologische Zeitschrift. 36 (3–4): 232–251. Bibcode:1962PalZ...36..232G. doi:10.1007/BF02986976. S2CID   140161473.
  5. "Determining stratigraphic tops". Geological digressions. 6 February 2019. Retrieved 19 January 2020.
  6. 1 2 3 Torell, O., 1870. Petrificata Suecana Formationis Cambricae. Lunds. Univ. Arsskr. 6. Avdel. 2, No. VIII, p. 1-14.
  7. 1 2 Opik, A., 1929. Studien uber das estnische Unterkambrium (Estonium). I-IV. Acta Comment. Univers. Tartuensis, A. 15(2), 56 p.
  8. 1 2 3 Miller, S.A. (1875). "Some new species of fossils from the Cincinnati group and remarks upon some described forms". Cincinnati Quarterly Journal of Science (2): 349–355.
  9. 1 2 Lisson, C.I., 1904. Los Tigillites del Salto del Fraile y algunes Sonneratia del Morro Solar. Cuerpo Ingen. Minas del Peru, Bol No 17, 64 p.
  10. 1 2 3 Smith, J. (1893). "Peculiar U-shaped tubes in sandstone near Crawfurdland Castle and in Gowkha Quarry, near Killwinning". Transactions of the Geological Society of Glasgow (9): 289–292.
  11. 1 2 3 Buatois, Luis; Mangano, M. Gabriela (2011). Ichnology: Organism-Substrate Interactions in Space and Time. New York: Cambridge University Press. p. 358. ISBN   978-0-521-85555-6.

Further reading