Caribbean large igneous province

Last updated September 26, 2023

The Caribbean large igneous province (CLIP) consists of a major flood basalt, which created this large igneous province (LIP). It is the source of the current large eastern Pacific oceanic plateau, of which the Caribbean-Colombian oceanic plateau is the tectonized remnant. The deeper levels of the plateau have been exposed on its margins at the North and South American plates. The volcanism took place between 139 and 69 million years ago, with the majority of activity appearing to lie between 95 and 88 Ma. The plateau volume has been estimated as on the order of 4 x 10⁶ km³. It has been linked to the Galápagos hotspot.^[1]

Proto-Caribbean Seaway

Divergence between the North American and South American Plates began to create oceanic crust off Colombia's Pacific coast by the end of the Jurassic (150 Ma). This divergence, which continued until at least 66 Ma, first resulted in a "proto-Caribbean spreading ridge" between these plates flanked by a perpendicular transform zone on its Pacific side. By 135–130 Ma, the subduction of the Farallon Plate had begun along this transform zone, effectively modifying it into a subduction zone and beginning the creation of the Great Caribbean Arch. This arch was formed around 120-115 Ma but must have been intersected by the Caribbean spreading ridge until 66 Ma. Hence, the Farallon Plate fed the spreading zone and later became the Caribbean Plate.^[2]

LIP formation

CLIP formed as a large igneous province and now forms a thickened zone of oceanic crust between the North American and South American Plates.^[3] In some places the oceanic crust is 2–3 times as thick as normal oceanic crust (15–20 km (9.3–12.4 mi) vs 7 km (4.3 mi). Its composition is similar to that of the Ontong Java Plateau.^[4]

Geochemical and geochronological evidences clearly indicate that the Galápagos hotspot initiated the formation of the CLIP 95-90 Ma in the eastern Pacific. From there it move north-east with the Farallon Plate between the two American plates until it collided with a volcanic arc, the Greater Antilles 60 million years later. Fragments of this voyage is preserved in accreted seamounts along the Central American coast and the Cocos and Carnegie Ridges. Isotopic profiles of Galápagos rocks can be matched with those from CLIP rocks.^[3]

92–63 Ma ⁴⁰Ar/³⁹Ar ages have been reported for the Curaçao Lava Formation and 94–83 ma for the Dumisseau Formation in Haiti, dating both locations back to the original LIP formation 94 Ma. CLIP volcanism originates from the plume-like source distinct from a MORB (mid-ocean ridge basalt) mantle. The long duration of CLIP volcanism can be explained by the interaction between a plume and the Greater Antilles subduction zone.^[5]

The margins of the CLIP have been uplifted and are exposed above sea level, which makes it unique among oceanic plateaus. It stretches 2,500 km (1,600 mi) east to west and 1,300 km (810 mi) north to south.^[6]^[7] The CLIP is composed of irregularly thickened (up to 20 km (12 mi)) oceanic crust of the Caribbean Plate and the deformed associated magmatic terranes obducted onto the Pacific coasts of northern South America, Central America, and the Antilles. One of the least deformed parts is Gorgona Island off Colombia's Pacific coast.^[6]^[7]^[8]

The CLIP was created during three phases of eruptions dating between the Aptian and the Maastrichtian: a first phase 124–112 Ma; the main magma production phase 94–83 Ma; and an 80–72 Ma phase. The youngest igneous rocks, in the Dominican Republic and Costa Rica, are from 63 Ma. That the CLIP originated in the Pacific is obvious because fragments of oceanic crust accreted to the margins of the Caribbean, for example on Hispaniola and Puerto Rico, contain fauna of Pacific provenance.^[9]

The Farallon Plate's eastward movement forced the northern half of the CLIP into the ocean basin that had opened between North and South America starting in the Jurassic. However, the mechanisms causing the NE movement of the CLIP remains unclear, especially considering the subduction in the Costa Rica-Panama arc initiated during the Campanian (83–72 Ma). The Galápagos hotspot is probably responsible for the main plume-related magmatic event 90 Ma, whilst the 76 Ma and 55 Ma event are related to lithospheric thinning in the Central Caribbean.^[9]

⁴⁰Ar/³⁹Ar dating have determined that the main magmatism occurred 95 to 83 million years ago (Ma) while a second pulse occurred 81-69 Ma. Around 86 Ma the arrival of a large plume initiated the Galápagos hotspot which resulted in volcanism over large parts of the Caribbean Plate and north-west South America. Renewed volcanism about 75 Ma has been attributed to either the Galápagos hotspot, thinning of the lithosphere coupled with associated melting and upwelling of plume-head material, or both.^[6]

Seismic and geochemical analyses, on the other hand, suggest the CLIP consists of several oceanic plateaus and palaeo-hotspot tracks formed 139-83 Ma some of which have been overprinted by later magmatism.^[6]^[10] If these first volcanic activities were generated by the Galápagos hotspot, it would make it the oldest still active hotspot on Earth.^[10]

Related Research Articles

A mantle plume is a proposed mechanism of convection within the Earth's mantle, hypothesized to explain anomalous volcanism. Because the plume head partially melts on reaching shallow depths, a plume is often invoked as the cause of volcanic hotspots, such as Hawaii or Iceland, and large igneous provinces such as the Deccan and Siberian Traps. Some such volcanic regions lie far from tectonic plate boundaries, while others represent unusually large-volume volcanism near plate boundaries.

In geology, hotspots are volcanic locales thought to be fed by underlying mantle that is anomalously hot compared with the surrounding mantle. Examples include the Hawaii, Iceland, and Yellowstone hotspots. A hotspot's position on the Earth's surface is independent of tectonic plate boundaries, and so hotspots may create a chain of volcanoes as the plates move above them.

The Trans-Mexican Volcanic Belt, also known as the Transvolcanic Belt and locally as the Sierra Nevada, is an active volcanic belt that covers central-southern Mexico. Several of its highest peaks have snow all year long, and during clear weather, they are visible to a large percentage of those who live on the many high plateaus from which these volcanoes rise.

A large igneous province (LIP) is an extremely large accumulation of igneous rocks, including intrusive and extrusive, arising when magma travels through the crust towards the surface. The formation of LIPs is variously attributed to mantle plumes or to processes associated with divergent plate tectonics. The formation of some of the LIPs in the past 500 million years coincide in time with mass extinctions and rapid climatic changes, which has led to numerous hypotheses about causal relationships. LIPs are fundamentally different from any other currently active volcanoes or volcanic systems.

The Iceland hotspot is a hotspot which is partly responsible for the high volcanic activity which has formed the Iceland Plateau and the island of Iceland.

Magmatism is the emplacement of magma within and at the surface of the outer layers of a terrestrial planet, which solidifies as igneous rocks. It does so through magmatic activity or igneous activity, the production, intrusion and extrusion of magma or lava. Volcanism is the surface expression of magmatism.

The Paraná-Etendeka Large Igneous Province (PE-LIP) (or Paraná and Etendeka Plateau; or Paraná and Etendeka Province) comprise a large igneous province that includes both the main Paraná traps (in Paraná Basin, a South American geological basin) as well as the smaller severed portions of the flood basalts at the Etendeka traps (in northwest Namibia and southwest Angola). The original basalt flows occurred 136 to 132 million years ago. The province had a post-flow surface area of 1,000,000 square kilometres (390,000 sq mi) and an original volume projected to be in excess of 2.3 x 10⁶ km³.

<span class="mw-page-title-main">Galápagos hotspot</span> Pacific volcanic hotspot

The Galápagos hotspot is a volcanic hotspot in the East Pacific Ocean responsible for the creation of the Galápagos Islands as well as three major aseismic ridge systems, Carnegie, Cocos and Malpelo which are on two tectonic plates. The hotspot is located near the Equator on the Nazca Plate not far from the divergent plate boundary with the Cocos Plate. The tectonic setting of the hotspot is complicated by the Galapagos Triple Junction of the Nazca and Cocos plates with the Pacific Plate. The movement of the plates over the hotspot is determined not solely by the spreading along the ridge but also by the relative motion between the Pacific Plate and the Cocos and Nazca Plates.

The Hikurangi Plateau is an oceanic plateau in the South Pacific Ocean east of the North Island of New Zealand. It is part of a large igneous province (LIP) together with Manihiki and Ontong Java, now located 3,000 km (1,900 mi) and 3,500 km (2,200 mi) north of Hikurangi respectively. Mount Hikurangi, in Māori mythology the first part of the North Island to emerge from the ocean, gave its name to the plateau.

The North Atlantic Igneous Province (NAIP) is a large igneous province in the North Atlantic, centered on Iceland. In the Paleogene, the province formed the Thulean Plateau, a large basaltic lava plain, which extended over at least 1.3 million km² (500 thousand sq mi) in area and 6.6 million km³ (1.6 million cu mi) in volume. The plateau was broken up during the opening of the North Atlantic Ocean leaving remnants preserved in north Ireland, west Scotland, the Faroe Islands, northwest Iceland, east Greenland, western Norway and many of the islands located in the north eastern portion of the North Atlantic Ocean. The igneous province is the origin of the Giant's Causeway and Fingal's Cave. The province is also known as Brito–Arctic province and the portion of the province in the British Isles is also called the British Tertiary Volcanic Province or British Tertiary Igneous Province.

The Manihiki Plateau is an oceanic plateau in the south-west Pacific Ocean. The Manihiki Plateau was formed by volcanic activity 126 to 116 million years ago during the mid-Cretaceous period at a triple junction plate boundary called the Tongareva triple junction. Initially at 125 million years ago the Manihiki Plateau formed part of the giant Ontong Java-Manihiki-Hikurangi plateau.

Ocean island basalt (OIB) is a volcanic rock, usually basaltic in composition, erupted in oceans away from tectonic plate boundaries. Although ocean island basaltic magma is mainly erupted as basalt lava, the basaltic magma is sometimes modified by igneous differentiation to produce a range of other volcanic rock types, for example, rhyolite in Iceland, and phonolite and trachyte at the intraplate volcano Fernando de Noronha. Unlike mid-ocean ridge basalts (MORBs), which erupt at spreading centers (divergent plate boundaries), and volcanic arc lavas, which erupt at subduction zones (convergent plate boundaries), ocean island basalts are the result of intraplate volcanism. However, some ocean island basalt locations coincide with plate boundaries like Iceland, which sits on top of a mid-ocean ridge, and Samoa, which is located near a subduction zone.

<span class="mw-page-title-main">Shatsky Rise</span> Oceanic plateau in the north-west Pacific Ocean

The Shatsky Rise is Earth's third largest oceanic plateau, located in the north-west Pacific Ocean 1,500 km (930 mi) east of Japan. It is one of a series of Pacific Cretaceous large igneous provinces (LIPs) together with Hess Rise, Magellan Rise, and Ontong Java-Manihiki-Hikurangi. It was named for Nikolay Shatsky (1895-1960), a Soviet geologist, expert in tectonics of ancient platforms.

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<span class="mw-page-title-main">Rarotonga hotspot</span> Volcanic hotspot in the southern Pacific Ocean

The Rarotonga hotspot is a volcanic hotspot in the southern Pacific Ocean. The hotspot is claimed to be responsible for the formation of Rarotonga and some volcanics of Aitutaki but an alternative explanation for these islands most recent volcanics has not been ruled out. Recently alternatives to hotspot activity have been offered for several other intra-plate volcanoes that may have been associated with the Rarotonga hotspot hypothesis.

Intraplate volcanism is volcanism that takes place away from the margins of tectonic plates. Most volcanic activity takes place on plate margins, and there is broad consensus among geologists that this activity is explained well by the theory of plate tectonics. However, the origins of volcanic activity within plates remains controversial.

References

Notes

↑ Courtillot & Renne 2003; Hoernle, Hauff & van den Bogaard 2004
↑ Serrano et al. 2011 , 5.2. Geodynamic setting during the formation of the CLIP, p. 332; Fig. 8, p. 333
1 2 Loewen et al. 2013 , Introduction, pp. 4241–4242
↑ Hauff et al. 2000 , 2. Geological background, pp. 248–249
↑ Loewen et al. 2013 , Conclusions, pp. 4256–4257
1 2 3 4 Courtillot & Renne 2003 , Introduction, p. 697
1 2 Geldmacher et al. 2003 , Introduction
↑ Serrano et al. 2011 , Introduction, pp. 324–325
1 2 Escuder-Viruete et al. 2011 , The Caribbean large igneous province, p. 309
1 2 Courtillot & Renne 2003 , p. 700

Sources

Courtillot, V. E.; Renne, P. R. (2003). "On the ages of flood basalt events (Sur l'âge des trapps basaltiques)" (PDF). Comptes Rendus Geoscience. 335 (1): 113–140. Bibcode:2003CRGeo.335..113C. CiteSeerX 10.1.1.461.3338 . doi:10.1016/S1631-0713(03)00006-3 . Retrieved 9 August 2015.
Escuder-Viruete, J.; Pérez-Estaun, A.; Joubert, M.; Weis, D. (2011). "The Pelona-Pico Duarte basalts Formation, Central Hispaniola: an on-land section of Late Cretaceous volcanism related to the Caribbean large igneous province" (PDF). Geologica Acta. 9 (3–4): 307–328. doi:10.1344/105.000001716 . Retrieved 9 August 2015.
Geldmacher, J.; Hanan, B. B.; Blichert‐Toft, J.; Harpp, K.; Hoernle, K.; Hauff, F.; Werner, R.; Kerr, A. C. (2003). "Hafnium isotopic variations in volcanic rocks from the Caribbean Large Igneous Province and Galápagos hot spot tracks" (PDF). Geochemistry, Geophysics, Geosystems. 4 (7): 1062. Bibcode:2003GGG.....4.1062G. doi:10.1029/2002GC000477. S2CID 13509777.
Hauff, F.; Hoernle, K.; Tilton, G.; Graham, D. W.; Kerr, A. C. (2000). "Large volume recycling of oceanic lithosphere over short time scales: geochemical constraints from the Caribbean Large Igneous Province" (PDF). Earth and Planetary Science Letters. 174 (3): 247–263. Bibcode:2000E&PSL.174..247H. doi:10.1016/s0012-821x(99)00272-1 . Retrieved 16 August 2015.
Hoernle, K.; Hauff, F.; van den Bogaard, P. (2004). "70 m.y. history (139–69 Ma) for the Caribbean large igneous province". Geology. 32 (8): 697–700. Bibcode:2004Geo....32..697H. doi:10.1130/G20574.1 . Retrieved 9 August 2015.
Loewen, M. W.; Duncan, R. A.; Kent, A. J. R.; Krawl, K. (2013). "Prolonged plume volcanism in the Caribbean Large Igneous Province: New insights from Curaçao and Haiti" (PDF). Geochemistry, Geophysics, Geosystems. 14 (10): 4241–4259. Bibcode:2013GGG....14.4241L. doi:10.1002/ggge.20273. S2CID 56052663 . Retrieved 9 August 2015.
Serrano, L.; Ferrari, L.; Martínez, M. L.; Petrone, C. M.; Jaramillo, C. (2011). "An integrative geologic, geochronologic and geochemical study of Gorgona Island, Colombia: Implications for the formation of the Caribbean Large Igneous Province" (PDF). Earth and Planetary Science Letters. 309 (3): 324–336. Bibcode:2011E&PSL.309..324S. doi:10.1016/j.epsl.2011.07.011 . Retrieved 9 August 2015.

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[1] Courtillot & Renne 2003; Hoernle, Hauff & van den Bogaard 2004

[2] Serrano et al. 2011 , 5.2. Geodynamic setting during the formation of the CLIP, p. 332; Fig. 8, p. 333

[Loewen-etal-p4241-3] 1 2 Loewen et al. 2013 , Introduction, pp. 4241–4242

[4] Hauff et al. 2000 , 2. Geological background, pp. 248–249

[5] Loewen et al. 2013 , Conclusions, pp. 4256–4257

[Court-Rene-Intro-6] 1 2 3 4 Courtillot & Renne 2003 , Introduction, p. 697

[Geldmacher_2003_loc=Introduction-7] 1 2 Geldmacher et al. 2003 , Introduction

[8] Serrano et al. 2011 , Introduction, pp. 324–325

[Escuder-etal-p309-9] 1 2 Escuder-Viruete et al. 2011 , The Caribbean large igneous province, p. 309

[Court-Rene-Conclusions-10] 1 2 Courtillot & Renne 2003 , p. 700

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