Igwisi Hills

Last updated
Igwisi Hills
Highest point
Elevation 1,146 m (3,760 ft) [1]
Coordinates 4°53′13.18″S31°56′4.46″E / 4.8869944°S 31.9345722°E / -4.8869944; 31.9345722 Coordinates: 4°53′13.18″S31°56′4.46″E / 4.8869944°S 31.9345722°E / -4.8869944; 31.9345722 [2]
Geography
LocationTanzania
Geology
Age of rock Pleistocene?
Mountain type Pyroclastic Cone
Last eruption 10450 BC

The Igwisi Hills are a volcanic field in Kaliua District of Tabora Region of Tanzania. Three tuff cones are found there, one of which is associated with a lava flow. They are one of the few locations of possibly kimberlitic lava flows on Earth.

Contents

The volcanoes are located in the middle of the Tanzania craton, away from other Tanzanian volcanoes. There have been prior episodes of kimberlitic volcanism in the craton, however.

The age of the Igwisi Hills is poorly known but may be early Holocene-late Pleistocene in age. Some rainfall-induced chemical modification is found, and the hills have a unique vegetation profile.

Geology

The Igwisi hills are formed by three tuff cones formed in the middle of the Tanzania craton. They are 70 metres (230 ft) above the landscape with a karst morphology and craters covered with grass, on a low ridge that may be the product of early eruptive stages. The northeastern hill has two craters, one with a breach from which a 500 metres (1,600 ft) long lava flow originates, probably formed when a lava lake in the crater escaped through a breach. The central volcano has a lava coulee and a tephra cone in its crater. [3] [4] [5] :72,73 [6] Craters have diameters of 200–400 metres (660–1,310 ft). [7] The total volume of these cones is less than 0.001 cubic kilometres (0.00024 cu mi). [6] Weak pyroclastic activity probably accompanied the eruptive activity. [3] Presumably, low intensity explosive activity built the cones, starting from the northeast cone and ending with the southwest cone. Afterwards, lava flows were generated. [8]

The Igwisi Hills are the only places in the world where possible kimberlite lava flows have been found, [9] in form of calcite-olivine lavas. [10] Kimberlite tuffs are also found, a rare species which is very susceptible to erosion. [11] True kimberlites are usually very old eruptive rocks, consequently any subsurface volcanic structure has long since been eroded away. [8] These kimberlites were erupted in a fairly nonexplosive fashion. [12] Not all researchers agree that these lavas are kimberlites, however, [13] with the low alkali content being cited as a difference although the Benfontein "kimberlites" share this property with the Igwisi hills ones. [14] If the Igwisi Hills aren't true kimberlites, the next youngest would be the 32.3 ± 2.2 Ma Kundelungu plateau pipes in the Democratic Republic of Congo. [8]

These kimberlites are also the youngest kimberlites in the world by over thirty million years, cosmogenic helium-3 dates of olivine indicates they were erupted in the late Pleistocene-Holocene, [15] some indicated ages being 11,200 ± 7,800 ± and 12,400 ± 4,800. [3] A poorly constrained U-Pb date is 0 ± 29 million years. The cones display a young morphology. [5] :72,73 The basement terrain belongs to the 2,500 ± 100 million year old Dodoman sequence. [3] The hills are remote from all other Tanzania volcanoes [1] but tectonic stresses imposed on the craton by the East African Rift System may have played a role in their genesis. [16] :3 Prior kimberlite activity in the Tanzania craton is recorded 1,150, 189 and 53 million years ago. [8]

The tuffs are highly calcitic, vesicular and contain numerous microxenoliths. The petrologically similar lavas show evidence of a differentiation by flow and gravity and have trachytic textures. [17] [5] :72,73 [7] Lavas have a carbonatitic composition. [4] Olivines with diopside cores are found at the Igwisi Hills. Garnet and orthopyroxene is associated with the diopside. [18] Olivines are surrounded by chromite. [7] Olivines characterize the texture of the Igwisi rocks, where they form spherical inclusions. The olivines are primarily forsteritic in composition. [19] Inclusions in the kimberlite include skeletal apatite, stellate aragonite and calcite. [20] High concentrations of CO2 are found in the rock, [12] which may have resulted in the depolymerization of the melt, increasing its fluidity and resulting in effusive activity. [21] Peridotite xenoliths originate from 180 kilometres (110 mi) of depth. [5] :15 Spinels in the groundmass suggest that crustal contamination was extensive, [21] with dunite nodules originating from the middle lithosphere, [16] :2 but isotope data instead indicate a low contamination. [16] :3 The geochemistry suggests an origin at high pressures (depths of 150–200 kilometres (93–124 mi)) and equilibrium temperatures of 1,000 °C (1,830 °F). [19] Rainfall has subsequently modified the pyroclastics and formed secondary calcite, while the less permeable lava flows were less modified. [8]

The hills have a unique vegetation, with aquatic plants found in the middle of the craters and distinct vegetation on inner crater slopes from the extra-crateric territory. [22] The hills have a rare occurrence of Asclepias pseudoamabilis . [23]

Related Research Articles

<span class="mw-page-title-main">Tuff</span> Rock consolidated from volcanic ash

Tuff is a type of rock made of volcanic ash ejected from a vent during a volcanic eruption. Following ejection and deposition, the ash is lithified into a solid rock. Rock that contains greater than 75% ash is considered tuff, while rock containing 25% to 75% ash is described as tuffaceous. Tuff composed of sandy volcanic material can be referred to as volcanic sandstone.

<span class="mw-page-title-main">Kimberlite</span> Igneous rock which sometimes contains diamonds

Kimberlite is an igneous rock and a rare variant of peridotite. It is most commonly known to be the main host matrix for diamonds. It is named after the town of Kimberley in South Africa, where the discovery of an 83.5-carat (16.70 g) diamond called the Star of South Africa in 1869 spawned a diamond rush and the digging of the open-pit mine called the Big Hole. Previously, the term kimberlite has been applied to olivine lamproites as Kimberlite II, however this has been in error.

<span class="mw-page-title-main">Nephelinite</span> Igneous rock made up almost entirely of nepheline and clinopyroxene

Nephelinite is a fine-grained or aphanitic igneous rock made up almost entirely of nepheline and clinopyroxene. If olivine is present, the rock may be classified as an olivine nephelinite. Nephelinite is dark in color and may resemble basalt in hand specimen. However, basalt consists mostly of clinopyroxene (augite) and calcic plagioclase.

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

A xenolith is a rock fragment that becomes enveloped in a larger rock during the latter's development and solidification. In geology, the term xenolith is almost exclusively used to describe inclusions in igneous rock entrained during magma ascent, emplacement and eruption. Xenoliths may be engulfed along the margins of a magma chamber, torn loose from the walls of an erupting lava conduit or explosive diatreme or picked up along the base of a flowing body of lava on the Earth's surface. A xenocryst is an individual foreign crystal included within an igneous body. Examples of xenocrysts are quartz crystals in a silica-deficient lava and diamonds within kimberlite diatremes. Xenoliths can be non-uniform within individual locations, even in areas which are spatially limited, e.g. rhyolite-dominated lava of Niijima volcano (Japan) contains two types of gabbroic xenoliths which are of different origin - they were formed in different temperature and pressure conditions.

<span class="mw-page-title-main">Peridotite</span> Coarse-grained ultramafic igneous rock type

Peridotite ( PERR-ih-doh-tyte, pə-RID-ə-) is a dense, coarse-grained igneous rock consisting mostly of the silicate minerals olivine and pyroxene. Peridotite is ultramafic, as the rock contains less than 45% silica. It is high in magnesium (Mg2+), reflecting the high proportions of magnesium-rich olivine, with appreciable iron. Peridotite is derived from Earth's mantle, either as solid blocks and fragments, or as crystals accumulated from magmas that formed in the mantle. The compositions of peridotites from these layered igneous complexes vary widely, reflecting the relative proportions of pyroxenes, chromite, plagioclase, and amphibole.

<span class="mw-page-title-main">Mount Morning</span> Volcano in Victoria Land, Antarctica

Mount Morning is a shield volcano at the foot of the Transantarctic Mountains in Victoria Land, Antarctica. It lies 100 kilometres (62 mi) from Ross Island. Mount Morning rises to an elevation of 2,723 metres (8,934 ft) and is almost entirely mantled with snow and ice. A 4.1 by 4.9 kilometres wide summit caldera lies at the top of the volcano and several ice-free ridges such as Hurricane Ridge and Riviera Ridge emanate from the summit. A number of parasitic vents mainly in the form of cinder cones dot the mountain.

<span class="mw-page-title-main">Lamproite</span> Ultrapotassic mantle-derived volcanic or subvolcanic rock

Lamproite is an ultrapotassic mantle-derived volcanic or subvolcanic rock. It has low CaO, Al2O3, Na2O, high K2O/Al2O3, a relatively high MgO content and extreme enrichment in incompatible elements.

<span class="mw-page-title-main">Komatiite</span> Ultramafic mantle-derived volcanic rock

Komatiite is a type of ultramafic mantle-derived volcanic rock defined as having crystallised from a lava of at least 18 wt% MgO. It is classified as a 'picritic rock'. Komatiites have low silicon, potassium and aluminium, and high to extremely high magnesium content. Komatiite was named for its type locality along the Komati River in South Africa, and frequently displays spinifex texture composed of large dendritic plates of olivine and pyroxene.

<span class="mw-page-title-main">Diatreme</span> Volcanic pipe associated with a gaseous explosion

A diatreme, sometimes known as a maar-diatreme volcano, is a volcanic pipe associated with a gaseous explosion. When magma rises up through a crack in Earth's crust and makes contact with a shallow body of groundwater, rapid expansion of heated water vapor and volcanic gases can cause a series of explosions. A relatively shallow crater is left, and a rock-filled fracture in the crust. Where diatremes breach the surface they produce a steep, inverted cone shape.

<span class="mw-page-title-main">Lascar (volcano)</span> A stratovolcano within the Central Volcanic Zone of the Andes

Lascar is a stratovolcano in Chile within the Central Volcanic Zone of the Andes, a volcanic arc that spans Peru, Bolivia, Argentina and Chile. It is the most active volcano in the region, with records of eruptions going back to 1848. It is composed of two separate cones with several summit craters. The westernmost crater of the eastern cone is presently active. Volcanic activity is characterized by constant release of volcanic gas and occasional vulcanian eruptions.

<span class="mw-page-title-main">Haruj</span> Libyan mountain range

Haruj is a large volcanic field spread across 42,000–45,000 km2 (16,000–17,000 sq mi) in central Libya. It is one of several volcanic fields in Libya along with Tibesti, and its origin has been attributed to the effects of geologic lineaments in the crust.

<span class="mw-page-title-main">Cinder cone</span> Steep hill of pyroclastic fragments around a volcanic vent

A cinder cone is a steep conical hill of loose pyroclastic fragments, such as volcanic clinkers, volcanic ash, or scoria that has been built around a volcanic vent. The pyroclastic fragments are formed by explosive eruptions or lava fountains from a single, typically cylindrical, vent. As the gas-charged lava is blown violently into the air, it breaks into small fragments that solidify and fall as either cinders, clinkers, or scoria around the vent to form a cone that often is symmetrical; with slopes between 30 and 40°; and a nearly circular ground plan. Most cinder cones have a bowl-shaped crater at the summit.

<span class="mw-page-title-main">Lava</span> Molten rock expelled by a volcano during an eruption

Lava is molten or partially molten rock (magma) that has been expelled from the interior of a terrestrial planet or a moon onto its surface. Lava may be erupted at a volcano or through a fracture in the crust, on land or underwater, usually at temperatures from 800 to 1,200 °C. The volcanic rock resulting from subsequent cooling is also often called lava.

<span class="mw-page-title-main">Udokan Plateau</span>

The Udokan Plateau is a volcanic field in Transbaikalia, Russia. It covers a surface area of 3,000 square kilometres (1,200 sq mi) northeast of Lake Baikal in North Asia. Volcanism in the Udokan Plateau included both basaltic lava flows and later individual volcanic cones. Volcanism commenced in the Miocene and continued on into the Holocene.

<span class="mw-page-title-main">Durango volcanic field</span> Volcanic field in Durango State, Mexico

Durango volcanic field is a volcanic field in north-central Mexico (Durango), east of the Sierra Madre Occidental. The field covers a surface area of 2,100 square kilometres (810 sq mi).

<span class="mw-page-title-main">Geology of Ascension Island</span>

The geology of Ascension Island is the geologically young, exposed part of a large volcano, 80 kilometers west of the Mid-Atlantic Ridge. The island formed within the last six to seven million years and is primarily mafic rock with some felsic rock.

<span class="mw-page-title-main">Archean felsic volcanic rocks</span> Felsic volcanic rocks formed in the Archean Eon

Archean felsic volcanic rocks are felsic volcanic rocks that were formed in the Archean Eon. The term "felsic" means that the rocks have silica content of 62–78%. Given that the Earth formed at ~4.5 billion year ago, Archean felsic volcanic rocks provide clues on the Earth's first volcanic activities on the Earth's surface started 500 million years after the Earth's formation.

<span class="mw-page-title-main">Honolulu Volcanics</span> Volcanic field in Oʻahu, Hawaiʻi

The Honolulu Volcanics are a group of volcanoes which form a volcanic field on the island of Oʻahu, Hawaiʻi, more specifically in that island's southeastern sector and in the city of Honolulu from Pearl Harbor to the Mokapu Peninsula. It is part of the rejuvenated stage of Hawaiian volcanic activity, which occurred after the main stage of volcanic activity that on Oʻahu built the Koʻolau volcano. These volcanoes formed through dominantly explosive eruptions and gave rise to cinder cones, lava flows, tuff cones and volcanic islands. Among these are well known landmarks such as Diamond Head and Punchbowl Crater.

<span class="mw-page-title-main">Lunar Crater volcanic field</span> Volcanic field in Nye County, Nevada

Lunar Crater volcanic field is a volcanic field in Nye County, Nevada. It lies along the Reveille and Pancake Ranges and consists of over 200 vents, mostly small volcanic cones with associated lava flows but also several maars, including one maar named Lunar Crater. Some vents have been eroded so heavily that the structures underneath the volcanoes have been exposed. Lunar Crater itself has been used as a testing ground for Mars rovers and as training ground for astronauts.

<span class="mw-page-title-main">Navajo volcanic field</span> Volcanic field in southwestern United States

The Navajo volcanic field is a monogenetic volcanic field located in the Four Corners region of the United States, in the central part of the Colorado Plateau. The volcanic field consists of over 80 volcanoes and associated intrusions of unusual potassium-rich compositions, with an age range of 26.2 to 24.7 million years (Ma).

References

  1. 1 2 "Igwisi Hills". Global Volcanism Program . Smithsonian Institution.
  2. Brown, R.J.; Sparks, R.S.J. "Mapping the Igwisi Hills kimberlite volcanoes, Tanzania: understanding how deep-sourced mantle magmas behave at the Earth's surface" (PDF). GEF Scientific Reports. Natural Environment Research Council . Retrieved 20 March 2016.
  3. 1 2 3 4 Brown, Richard J.; Manya, S.; Buisman, I.; Fontana, G.; Field, M.; Niocaill, C. Mac; Sparks, R. S. J.; Stuart, F. M. (13 June 2012). "Eruption of kimberlite magmas: physical volcanology, geomorphology and age of the youngest kimberlitic volcanoes known on earth (the Upper Pleistocene/Holocene Igwisi Hills volcanoes, Tanzania)" (PDF). Bulletin of Volcanology. 74 (7): 1621–1643. Bibcode:2012BVol...74.1621B. doi:10.1007/s00445-012-0619-8. S2CID   55963140.
  4. 1 2 Dawson, J. Barry (1980). "Distribution and Tectonic Setting of Kimberlites". Kimberlites and Their Xenoliths. Minerals and Rocks. Vol. 15. Berlin, Heidelberg: Springer Berlin Heidelberg. p. 9. doi:10.1007/978-3-642-67742-7_2. ISBN   978-3-642-67742-7.
  5. 1 2 3 4 Dawson, John Barry (2008). The Gregory Rift Valley and Neogene-recent Volcanoes of Northern Tanzania. Geological Society of London. ISBN   9781862392670 . Retrieved 28 February 2016.
  6. 1 2 Brown, R. J.; Valentine, G. A. (7 June 2013). "Physical characteristics of kimberlite and basaltic intraplate volcanism and implications of a biased kimberlite record" (PDF). Geological Society of America Bulletin. 125 (7–8): 1226. Bibcode:2013GSAB..125.1224B. doi:10.1130/B30749.1.
  7. 1 2 3 Mitchell, Roger H. (2013-06-29). Kimberlites: Mineralogy, Geochemistry, and Petrology. Springer Science & Business Media. pp. 31–32. ISBN   9781489905680 . Retrieved 28 February 2016.
  8. 1 2 3 4 5 Willcox, A.; Buisman, I.; Sparks, R.S.J.; Brown, R.J.; Manya, S.; Schumacher, J.C.; Tuffen, H. (June 2015). "Petrology, geochemistry and low-temperature alteration of lavas and pyroclastic rocks of the kimberlitic Igwisi Hills volcanoes, Tanzania". Chemical Geology. 405: 82–101. Bibcode:2015ChGeo.405...82W. doi:10.1016/j.chemgeo.2015.04.012.
  9. Mitchell, Roger H. (1995). Kimberlites, Orangeites, and Related Rocks. Springer Science & Business Media. p. 37. ISBN   978-1-4613-5822-0 . Retrieved 28 February 2016.
  10. Sparks, R.S.J.; Baker, L.; Brown, R.J.; Field, M.; Schumacher, J.; Stripp, G.; Walters, A (July 2006). "Dynamical constraints on kimberlite volcanism". Journal of Volcanology and Geothermal Research. 155 (1–2): 18–48. Bibcode:2006JVGR..155...18S. doi:10.1016/j.jvolgeores.2006.02.010.
  11. Chalapathi Rao, N. V.; Anand, M.; Dongre, A.; Osborne, I. (10 September 2009). "Carbonate xenoliths hosted by the Mesoproterozoic Siddanpalli Kimberlite Cluster (Eastern Dharwar craton): implications for the geodynamic evolution of southern India and its diamond and uranium metallogenesis". International Journal of Earth Sciences. 99 (8): 1791–1804. doi:10.1007/s00531-009-0484-7. S2CID   128822277.
  12. 1 2 Brooker, Richard A.; Sparks, R. Stephen J.; Kavanagh, Janine L.; Field, Matthew (8 September 2011). "The volatile content of hypabyssal kimberlite magmas: some constraints from experiments on natural rock compositions". Bulletin of Volcanology. 73 (8): 959–981. Bibcode:2011BVol...73..959B. doi:10.1007/s00445-011-0523-7. S2CID   131412395.
  13. White, J.D.L.; Ross, P.-S. (April 2011). "Maar-diatreme volcanoes: A review" (PDF). Journal of Volcanology and Geothermal Research. 201 (1–4): 1–29. Bibcode:2011JVGR..201....1W. doi:10.1016/j.jvolgeores.2011.01.010.
  14. BATUMIKE, J; GRIFFIN, W; BELOUSOVA, E; PEARSON, N; OREILLY, S; SHEE, S (30 March 2008). "LAM-ICPMS U–Pb dating of kimberlitic perovskite: Eocene–Oligocene kimberlites from the Kundelungu Plateau, D.R. Congo". Earth and Planetary Science Letters. 267 (3–4): 609–619. Bibcode:2008E&PSL.267..609B. doi:10.1016/j.epsl.2007.12.013.
  15. D. Graham Pearson; et al., eds. (2013). "How Structure and Stress Influence Kimberlite Emplacement". Proceedings of 10th International Kimberlite Conference. New Delhi: Springer. p. 56. doi:10.1007/978-81-322-1173-0_4. ISBN   978-81-322-1173-0.
  16. 1 2 3 Shaikh, Azhar M.; Tappe, Sebastian; Bussweiler, Yannick; Vollmer, Christian; Brown, Richard J. (31 July 2021). "Origins of olivine in Earth's youngest kimberlite: Igwisi Hills volcanoes, Tanzania craton". Contributions to Mineralogy and Petrology. 176 (8): 62. Bibcode:2021CoMP..176...62S. doi:10.1007/s00410-021-01816-2. hdl: 10037/23882 . ISSN   1432-0967. S2CID   236523877.
  17. Dawson, J. Barry (1980). "Geology of Kimberlite Intrusions". Kimberlites and Their Xenoliths. Minerals and Rocks. Vol. 15. Berlin, Heidelberg: Springer Berlin Heidelberg. p. 37. doi:10.1007/978-3-642-67742-7_2. ISBN   978-3-642-67742-7.
  18. Sazonova, L. V.; Nosova, A. A.; Kargin, A. V.; Borisovskiy, S. E.; Tretyachenko, V. V.; Abazova, Z. M.; Griban, Yu. G. (12 May 2015). "Olivine from the Pionerskaya and V. Grib kimberlite pipes, Arkhangelsk diamond province, Russia: Types, composition, and origin". Petrology. 23 (3): 252. doi:10.1134/S0869591115030054. S2CID   126520733.
  19. 1 2 Reid, Arch M.; Donaldson, C.H.; Dawson, J.B.; Brown, R.W.; Ridley, W.I. (January 1975). "The Igwisi Hills extrusive "kimberlites"". Physics and Chemistry of the Earth. 9: 199–218. Bibcode:1975PCE.....9..199R. doi:10.1016/0079-1946(75)90017-8.
  20. Dawson, J. Barry (1980). Kimberlites and Their Xenoliths. Berlin, Heidelberg: Springer Berlin Heidelberg. pp. 88–92. ISBN   978-3-642-67742-7.
  21. 1 2 van Straaten, Bram I.; Kopylova, M. G.; Russell, J. K.; Scott Smith, B. H. (25 June 2011). "A rare occurrence of a crater-filling clastogenic extrusive coherent kimberlite, Victor Northwest (Ontario, Canada)". Bulletin of Volcanology. 73 (8): 1057. Bibcode:2011BVol...73.1047V. doi:10.1007/s00445-011-0507-7. S2CID   58896592.
  22. Cantrill, David J.; Bamford, Marion K.; Wagstaff, Barbara E.; Sauquet, Hervé (September 2013). "Early Eocene fossil plants from the Mwadui kimberlite pipe, Tanzania". Review of Palaeobotany and Palynology. 196: 19–35. doi:10.1016/j.revpalbo.2013.04.002.
  23. Goyder, D. J. (18 October 2009). "A synopsis of Asclepias (Apocynaceae: Asclepiadoideae) in tropical Africa". Kew Bulletin. 64 (3): 380. doi:10.1007/s12225-009-9133-3. S2CID   37633722.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.