Armored mud ball explained

An armored mud ball is a small sedimentary structure, formed in flowing water, which consists of a fragment of clay or mud that has been rolled by currents into a spherical shape, and which then becomes coated in a layer of sand, gravel or pebbles that serves to protect (armor) it against further breakdown.[1] [2] Armored mud balls can vary in size from less than a centimeters up to 50 centimeters in diameter. Typically, they are between 5 and 10 centimeters in diameter. Mud balls are known to form in many parts of the world, and armored mud balls can form in river, lake or marine environments.[3]

Under circumstances of rapid burial, armored mud balls can become incorporated into other sediments which subsequently form sedimentary rocks. Exposures of these lithified armored mud balls are very rare, but are known from a small number of locations around the world.[4] [5] [6] [7]

Etymology

The name "pudding balls" was originally given to these structures by geologist Lon D. Cartwright Jr. in 1928.[8] However, because the pebbles that protect them are not spread evenly throughout the clay body, but are found only on the outer surface, the name 'armored mud ball' was proposed in 1940 by geologist Hugh Stevens Bell, and has since been widely adopted.[9] [10]

Formation

Pre-lithification

In the early 20th century, James Gardner hypothesized that these structures formed by the accumulation of fine clay particles as they flowed along a stream, gradually building up concentric rings of sediments by adhesion until their weight eventually stopped them rolling with the current.[11] That view held sway for some 20 years, despite an earlier suggestion in 1875 by Jones and King that those mud balls found on beaches had formed from broken off fragments of clay from adjacent cliffs which had then been rolled by wave action.[12]

By 1940 it was generally accepted that their formation was due to rolling of broken off fragments of clay and not to concretion.

Armored mud balls are derived from fragments of clay or mud that get broken off from their original sediment layers deposits by erosion, commonly in places such as sea cliffs or the cut bank of a river. The mud fragments are washed and rolled by flowing water and become covered in larger particles from the bed of the watercourse.[13] The particles, typically sand or pebbles, form an "armor" that allows the mud ball to retain its shape during transport. This is especially important for armored mud balls that form in deep-ocean sediment flows known as turbidity currents, where fragments of mud initially eroded from submarine canyons become coated with a sand armor that allows them to travel for tens of kilometers without being destroyed. Armored mud balls formed by wave action in beach environments can sometimes carry an armor of seashell fragments instead of pebbles.

Lithification

Despite their name, armored mud balls are typically quite fragile and often disintegrate after drying out, making them a rare occurrence in the geologic record. However, if armored mud balls are buried quickly, there is a chance that they may become lithified along with their entombing sediment and get preserved for millions of years. The mud balls themselves are preserved as small chunks of mudstone or siltstone surrounded by a ring of pebbles.

Examples

Teichert & Kummel (1972) described armored mud balls from the Kap Stosch area of East Greenland. These specimens were unusual because their cores had been eroded, but part of the armor included fossils that had been eroded from older layers and redeposited along with the armored mud balls in Triassic sediments.

Richter (1926) found an armored mud ball from Eocene age sediments near Vienna, Austria.

Cartwright (1928) described "pudding balls" from the Pliocene Pico Formation of the Ventura Quadrangle, California.

Kugler & Saunders (1959) mention armored mud balls from the Miocene of Trinidad, the Eocene of Ecuador, and the Jurassic of Spitsbergen. The Spitsbergen examples have shell fragments for armor, indicating they formed in a beach environment.

Stanley (1964) described armored mud balls in Eocene submarine channel deposits from France.

Little (1982) discovered very well-preserved armored mud balls in alluvial fan deposits of the Lower Jurassic Turners Falls Sandstone from Turners Falls, Massachusetts. A total of 25 armored mud balls were found in quarried sandstone blocks that used to serve as cable anchors for a now-defunct suspension bridge over the Connecticut River. Subsequent investigations by Little revealed more armored mud balls from the Turners Falls Formation in the towns of Turners Falls and Gill, as well as the Upper Triassic Sugarloaf Formation in the towns of Greenfield and Deerfield, Massachusetts.[14] The examples from the Connecticut River Valley of Western Massachusetts are particularly notable because they are among the most well-preserved and easily accessible lithified armored mud balls in the world.

See also

External links

Notes and References

  1. Web site: Armoured mud ball . www.britannica.com . Britannica . 23 July 2022 . en . 24 July 2022 . https://web.archive.org/web/20220724114027/https://www.britannica.com/science/armoured-mud-ball . live .
  2. Hizzett . Jamie L. . Sumner . Esther J. . Cartigny . Matthieu J. B. . Clare . Michael A. . July 21, 2020 . Mud-clast armoring and its implications for turbidite systems . Journal of Sedimentary Research . 90 . 7 . 687–700 . 10.2110/jsr.2020.35 . 225616357 . GeoScience World . August 10, 2022 . August 10, 2022 . https://web.archive.org/web/20220810182125/https://pubs.geoscienceworld.org/sepm/jsedres/article-abstract/90/7/687/588089/Mud-clast-armoring-and-its-implications-for . live .
  3. Tanner . Lawrence H. . 1 August 1996 . Armoured mud balls revisited . Atlantic Geology . 32 . 2 . 10.4138/2082 . 23 July 2022. free .
  4. Teichert . Curt . Kummel . Bernhard . December 1, 1972 . PERMIAN-TRIASSIC BOUNDARY IN THE KAP STOSCH AREA, EAST GREENLAND . Bulletin of Canadian Petroleum Geology . 20 . 4 . 659–675 . GeoScience World . August 10, 2022 . August 10, 2022 . https://web.archive.org/web/20220810182126/https://pubs.geoscienceworld.org/cspg/bcpg/article-abstract/20/4/659/57062/PERMIAN-TRIASSIC-BOUNDARY-IN-THE-KAP-STOSCH-AREA . live .
  5. Kugler . H. G. . Saunders . J. B. . 1959 . Occurrence of Armored Mud Balls in Trinidad, West Indies . The Journal of Geology . 67 . 5 . 563–565 . 10.1086/626607 . 30056108 . 1959JG.....67..563K . 129637285 . 0022-1376 . 2022-08-10 . 2022-07-19 . https://web.archive.org/web/20220719160349/https://www.jstor.org/stable/30056108 . live .
  6. Stanley . Daniel J. . September 1, 1964 . Large mudstone-nucleus sandstone spheroids in submarine channel deposits . Journal of Sedimentary Research . 34 . 3 . 672–676 . 10.1306/74D71136-2B21-11D7-8648000102C1865D . 1964JSedR..34..672S . GeoScience World . August 10, 2022 . November 8, 2023 . https://web.archive.org/web/20231108152104/https://pubs.geoscienceworld.org/sepm/jsedres/article-abstract/34/3/672/95780/Large-mudstone-nucleus-sandstone-spheroids-in . live .
  7. Richter . Rudolf . 1926 . Die entstehung von tongerollen und tongallen unter wasser: Flachseebeobachtungen zur Pal. u. Geol., XVI . Senchkenbergiana . VIII . 5/6 . 305–315.
  8. Cartwright . L.D. . Sedimentation of the Pico Formation in the Ventura Quadrangle, California. . American Association of Petroleum Geologists Bulletin . 1928 . 12 . 3 . 10.1306/3D9327E8-16B1-11D7-8645000102C1865D . 2022-08-10 . 2022-08-10 . https://web.archive.org/web/20220810184627/https://pubs.geoscienceworld.org/aapgbull/article-abstract/12/3/235/544349/Sedimentation-of-the-Pico-Formation-in-the-Ventura?redirectedFrom=PDF . live .
  9. Bachmann . Gerhard H. . Wang . Yuan . Armoured mud balls as a result of ephemeral fluvial flood in a humid climate: Modern example from Guizhou Province, South China . Journal of Palaeogeography . 1 October 2014 . 3 . 4 . 410–418 . 23 July 2022 . en . 2095-3836 . 23 July 2022 . https://web.archive.org/web/20220723235834/https://www.sciencedirect.com/science/article/pii/S2095383615300936 . live .
  10. Bell . Hugh Stevens . Armored Mud Balls: Their Origin, Properties, and Role in Sedimentation . The Journal of Geology . 1 January 1940 . 48 . 1 . 1–31 . 10.1086/624859 . 1940JG.....48....1B . 140549562 . 23 July 2022 . 0022-1376 . 23 July 2022 . https://web.archive.org/web/20220723235839/https://www.journals.uchicago.edu/doi/10.1086/624859 . live .
  11. Gardner . James H. . The Physical Origin of Certain Concretions . The Journal of Geology . 1908 . 16 . 5 . 452 . 10.1086/621531 . 1908JG.....16..452G . 128985851 . 2022-08-30 . 2023-11-08 . https://web.archive.org/web/20231108152049/https://zenodo.org/records/2048785 . live .
  12. Jones . T. Rupert . Thomas Rupert Jones . King . C.Cooper . On some newly exposed Sections of the "Woolwich and Reading Beds" at Reading, Berks. Quarterly Journal of the Geological Society. 1875 . 31 . 1–4 . 451–57. 10.1144/GSL.JGS.1875.031.01-04.32 . 129568207 .
  13. Little . Richard D. . 1982 . Lithified Armored Mud Balls of the Lower Jurassic Turners Falls Sandstone, North-Central Massachusetts . The Journal of Geology . 90 . 2 . 203–207 . 10.1086/628665 . 30070759 . 1982JG.....90..203L . 140571464 . 0022-1376 . 23 July 2022 . 19 July 2022 . https://web.archive.org/web/20220719160350/https://www.jstor.org/stable/30070759 . live .
  14. Book: Little, R. D. . Exploring Franklin County, Western Massachusetts: Your Guide to Amazing Stories in Rocks & Landscapes. . Earth View LLC . 2020 . Easthampton, MA.