Jump to content

Antalo Limestone

Coordinates: 13°35′52″N 39°16′38″E / 13.5977°N 39.2772°E / 13.5977; 39.2772
From Wikipedia, the free encyclopedia

This is an old revision of this page, as edited by 73.43.32.48 (talk) at 01:23, 15 September 2022. The present address (URL) is a permanent link to this revision, which may differ significantly from the current revision.

Antalo Limestone
Stratigraphic range: Oxfordian-Kimmeridgian
~163–153 Ma
Formation at Kurkura village (Dogua Tembien), holding St. Mika'el's cave
TypeGeological formation
UnderliesMugher Mudstone
OverliesAdigrat Sandstone
Thickness800 m (2,600 ft)
Lithology
PrimaryLimestone, marl, calcareous sandstone
OtherGrainstone, wackestone
Location
Coordinates13°35′52″N 39°16′38″E / 13.5977°N 39.2772°E / 13.5977; 39.2772
Approximate paleocoordinates7°30′S 26°36′E / 7.5°S 26.6°E / -7.5; 26.6
RegionTigray
Country Ethiopia
 Eritrea
ExtentMekelle Outlier, Danakil Alps
Type section
Named forAntalo town
Named byWilliam Thomas Blanford
Year defined1868
Antalo Limestone is located in Ethiopia
Antalo Limestone
Antalo Limestone (Ethiopia)

The Antalo Limestone, also known as the Antalo Sequence, is a geological formation in Ethiopia. It is between 300 and 800 metres thick and comprises fossiliferous limestones and marls that were deposited in a reef. Marine microfossils have shown an age between 165 and 150 million years.[1][2]

Name and definition

The Antalo Supersequence includes two main stratigraphic units: the Antalo Sequence and the Agula Group.[2][3] The Antalo Sequence, or Antalo Limestone has been named after the town of Hintalo in Tigray, Ethiopia. The name of the formation was coined by geologist William Thomas Blanford, who accompanied the British Expedition to Abyssinia in 1868.[4] At that time, Hintalo was a major town on the route of the invading British army.[5] So far the nomenclature has not been proposed for recognition to the International Commission on Stratigraphy.

Geographical extent

The sedimentary succession is found in Ethiopia, in the Mekelle Outlier, in the Blue Nile gorge, in the Harrar Plateau and around Dire Dawa.[2]

Stratigraphic context

The Antalo Limestone overlies the Adigrat Sandstone, and is covered by the Agula Group or Agula Shale and the Mugher Mudstone.

Environment

The Antalo Limestone comprises sediment that was deposited in a shallow tropical sea in the upper Jurassic. As the region had undergone a marine transgression, it was below the sea level. At that time, what would become Ethiopia was positioned just south of the equator.[6]

Lithology

Quarry in the third member of Antalo Limestone at May Qarano in Dogu’a Tembien

The limestones and marls of the Antalo Sequence also hold shale and calcareous sandstone layers. The Antalo Limestone comprises four members: (1) a basal member with grainstone and wackestone lithologies, with marly interlayers and in the upper part stromatoporoid coral-like level; (2) sandy limestone deposited in estuaries and lagoons; (3) micritic (very fine grained) limestone with intercalations of wackestone and coquina beds deposited in relatively deep water; and (4) a succession of marls and limestone, with cherty limestone at the base.[2][3]

Rock sample of sandy limestone (second member), collected in Addi Idaga
Rock sample from the fourth (upper) member, collected in Miheno

Fossil content

Rock sample of Antalo Limestone with mollusks, collected in Azef

The Antalo Limestone sediments were deposited at the time of dinosaurs and primitive birds. Well away from coasts, coral reefs formed the edge of the continental shelf. At shallow depth, the sea bottom was made of large mudflats, with sand bars and spits near river mouths.[6] This sea bed hosted many invertebrate animals: echinoderms, crustaceans, bivalves and gastropods were common. There was also fish. As it was not a nutrient-rich ecosystem, larger predators were rare, maybe some marine reptiles like crocodiles. A striking scavenger in this fauna was a cephalopod mollusc, a giant nautilus with a characteristic spiral shell.[6]

Invertebrates

Bivalves[7]
Genus Species Presence Material Notes Images
Actinostreon A. solitarium 10 specimens from AL1, 65 from AL2. 75 specimens. A palaeolophid.
Arcomytilus A. laitmairensis AL1 and AL2. 3 left valves, 1 right valve and 4 articulated specimens. A mytilid.
Eopecten E. velatus AL1. 1 left valve. A pectinid.
Gryphaea G.? (Bilobissa?) balli AL1. 1 left valve. A gryphaeid.
Integricardium I. (Integricardium) cf. bannesianum 7 specimens from AL1, 1 from AL2. 4 left valves, 1 right valves and 3 double-valved specimens. A cardiid.
Liostrea L. sp. AL1 and AL2. 2 specimens. An ostreid.
"Lucina" "L." cf. cecchii AL2. 4 double-valved specimens. A lucinid.
Modiolus M. (Modiolus) imbricatus 2 specimens from AL1, 1 from AL2. 3 double-valved specimens. A mytilid.
Musculus M. (Musculus) somaliensis AL1 and AL2. 2 articulated specimens. A mytilid.
Nanogyra N. nana AL2. 2 articulated specimens. A gryphaeid.
Pholadomya P. (Bucardiomya) somaliensis 1 specimen from AL1, 6 from AL2. 7 double-valved specimens. A pholadomyid.
P. (Bucardiomya) lirata AL2. 1 double-valved specimen. A pholadomyid.
Plagiostoma P. harronis AL1 and AL2. 3 left valves, 5 right valves and 2 articulated specimens. A limid.
P. sublaeviusculum AL2. 1 left valve 1 right valve and 1 articulated specimen. A limid.
Seebachia S. ("Eoseebachia") sowerbyana AL2. 2 left valves. An astartid.
Spondylopecten S. (Spondylopecten) palinurus AL1. 2 left valves. A pectinid.
Stegoconcha S. gmuelleri AL2. 2 articulated specimens. A pinnid.
Brachiopods[7]
Genus Species Presence Material Notes Images
cf. Amydroptychus cf. A. sp. Base of AL2. 10 individuals. A rhynchonellid.
Cererithyris C. sp. 1 from AL1, 105 from AL2 . 106 individuals. A terebratulid.
Cymatorhynchia C. sp. AL2. 16 individuals. A rhynchonellid.
Daghanirhynchia D. sp. 3 individuals from AL1, 51 from AL2. 54 individuals. A rhynchonellid.
Monsardithyris M. sp. AL2. 20 individuals. A terebratulid.
Somalirhynchia S. africana Mostly from AL2. More than 100 individuals. A rhynchonellid.
Cnidarians[7]
Genus Species Presence Material Notes Images
Actinastrea A. crassoramosa 47 specimens from AL1, 13 from AL2. 60 larger fragments of colonies. A stony coral.
Coenastraea C. arabica AL2. 1 specimen. A stony coral.
Collignonastraea C. cf. grossouvrei AL2. 1 specimen. A stony coral.
Columnocoenia C. gemmans AL1. 2 specimens. A stony coral.
Comoseris C. meandrinoides AL3. 1 complete colony. A stony coral.
Cladophyllia C. excelsa AL3. 1 specimen. A stony coral.
Cryptocoenia C. slovenica 7 specimens from AL1, 4 specimens from AL2. 11 specimens. A stony coral.
Ironella I. arabica AL1. 12 specimens. A stony coral.
Isastrea I. bernensis 20 specimens from AL1, 22 specimens from AL2. 42 specimens. A stony coral.
Kobyastraea K. lomontiana AL1. 1 specimen. A stony coral.
Latiastrea L. greppini 2 from AL1, 3 from AL2. 5 specimens. A stony coral.
Lochmaeosmilia L. trapeziformis AL1. 16 karger fragments of colonies. A stony coral.
Ovalastrea O. michelini AL2. 3 specimens (including 1 complete colony). A stony coral.
Echinoderms
Genus Species Presence Material Notes Images
Ausichicrinites A. zelenskyyi Nearly complete specimen.[8] A comatulid.
Pygurus P. meslei Upper part of the formation.[9] A sea urchin.
Molluscs[10]
Genus Species Presence Material Notes Images
Orthosphinctes O. aff. tiziani Top part of sub-unit II. 5 fragmentary specimens. An ataxioceratid ammonite.
Pachyceras P. cf. lalandeanum From the middle part of sub-unit II, GPS location 10°02′39.7″N, 38°13′53.7″E. One poorly preserved specimen (no. AF020). A pachyceratid ammonite.
Paracenoceras P. cf. ennianus Top part of sub-unit II. 1 specimen (no. AF012). A nautiloid.
P. aff. prohexagonum Lower Limestone Member.[11] A nautiloid.
P. cf. kumagunense Top part of sub-unit II. 1 specimen (no. AF004). A nautiloid.
P. cf. giganteum Middle part of sub-unit II. 1 specimen (no. AF005). A nautiloid.
Purpuroidea P. aff. gigas One specimen (AF025) from the top part of sub-unit I; One specimen (AF026) from the top part of sub-unit II. 2 specimen (AF025 and AF026). A gastropod.

Limestone and karst geomorphology

A spring in Antalo Limestone at Santarfa

The layering is sub-horizontal, the same as that of the underlying sedimentary formations.[3] This gives rise to a structural sub-horizontal relief, with alternating cliffs and flats. Dissolution processes in limestone lead to the occurrence of caves. Most described caves in Mesozoic limestone in Ethiopia are located in the Harrar region (Sof Omar cave) and in the Dogu’a Tembien district of Tigray.[12]

Traditional uses of Antalo Limestone

Antalo Limestone is commonly used for house building; here a homestead in Addi Ateroman in Dogu’a Tembien

Given its nearly rectangular shape and its strength, the hard layers of Antalo Limestone are used for

See also

References

  1. ^ Sembroni, A.; Molin, P.; Dramis, F. (2019). Regional geology of the Dogu'a Tembien massif. In: Geo-trekking in Ethiopia's Tropical Mountains - The Dogu'a Tembien District. SpringerNature. ISBN 978-3-030-04954-6.
  2. ^ a b c d Bosellini, A.; Russo, A.; Fantozzi, P.L.; Assefa, G.; Tadesse, S. (1997). "The Mesozoic succession of the Mekelle Outlier (Tigrai Province, Ethiopia)". Mem. Sci. Geol. 49: 95–116.
  3. ^ a b c Dramis, F.; Fubelli, G. (2019). "Limestone, Karst and Tufa Dams in the Western Part of the Mekelle Outlier". Geo-trekking in Ethiopia's Tropical Mountains. GeoGuide. Cham (CH): SpringerNature. pp. 107–119. doi:10.1007/978-3-030-04955-3_7. ISBN 978-3-030-04954-6.
  4. ^ Blanford, W.T. (1870). Observations on the geology and zoology of Abyssinia, made during the progress of the British expedition to that country in 1867-68. London: Macmillan and Co.
  5. ^ Markham, C.; Prideaux, W. (1869). A history of the Abyssinian expedition. Macmillan.
  6. ^ a b c Lerouge, F.; Aerts, R. (2019). Fossil evidence of Dogu'a Tembien's environmental past. In: Geo-Trekking in Ethiopia's Tropical Mountains, the Dogu'a Tembien District. SpringerNature. ISBN 978-3-030-04954-6.
  7. ^ a b c Kiessling, Wolfgang; Pandey, Dhirendra Kumar; Schemm-Gregory, Mena; Mewis, Heike; Aberhan, Martin (2011). "Marine benthic invertebrates from the Upper Jurassic of northern Ethiopia and their biogeographic affinities". Journal of African Earth Sciences. 59 (2–3): 195. ISSN 1464-343X.
  8. ^ Salamon, Mariusz A.; Jain, Sreepat; Brachaniec, Tomasz; Duda, Piotr; Płachno, Bartosz J.; Gorzelak, Przemysław. "Ausichicrinites zelenskyyi gen. et sp. nov., a first nearly complete feather star (Crinoidea) from the Upper Jurassic of Africa". Royal Society Open Science. 9 (7): 220345. doi:10.1098/rsos.220345. PMC 9297031. PMID 35875469.
  9. ^ Radwańska, Urszula; Jain, Sreepat (2020-10-01). "First Late Jurassic echinoid record of Pygurus meslei Gauthier from the Antalo Limestone Formation (Blue Nile Basin, Ethiopia)". Journal of African Earth Sciences. 170: 103898. doi:10.1016/j.jafrearsci.2020.103898. ISSN 1464-343X.
  10. ^ Jain, Sreepat; Schmerold, Roland (2021). "Callovian and Kimmeridgian fossils and stratigraphy of the Blue Nile Basin (central western Ethiopia)". Annales Societatis Geologorum Poloniae. doi:10.14241/asgp.2021.11. ISSN 0208-9068.
  11. ^ Jain, Sreepat (2019-01-01). "First Bathonian (Middle Jurassic) nautiloid Paracenoceras Spath from Ethiopia". Journal of African Earth Sciences. 149: 84–96. doi:10.1016/J.JAFREARSCI.2018.07.027. ISSN 1464-343X.
  12. ^ Catlin, D; Largen, M; Monod, T; Morton, W (1973). "The caves of Ethiopia". Transactions of the Cave Research Group of Great Britain. 15: 107–168.
  13. ^ Nixon-Darcus, L.A. (2014). The cultural context of food grinding equipment in Northern Ethiopia: an ethnoarchaeological approach. PhD thesis. Canada: Simon Frazer University.
  14. ^ Gebre Teklu (2012). Ethnoarchaeological study of grind stones at Lakia'a in Adwa, Tigray Regional State, Ethiopia. PhD diss (PDF). Addis Ababa University.