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Galápagos Microplate

April 10, 2024

The Galapagos Microplate (GMP) is a geological feature of the oceanic crust located at 1°50' N, offshore of the west coast of Colombia. The GMP is collocated with the Galapagos Triple Junction, which is an atypical ridge-ridge-ridge triple junction. At the Galapagos Triple Junction, the Pacific Plate, Cocos Plate, and Nazca Plate meet incompletely, forming two counter-rotating microplates at the junction of the Cocos-Nazca, Pacific-Cocos, and Pacific-Nazca spreading ridges.[1]

Geological evolution edit

The entire Galapagos Microplate, which covers an area of 13,000 km2, was formed to accommodate the motions of three major moving plates. Before the formation of the Galapagos Microplate, the Galapagos Triple Junction was a conventional ridge-ridge-ridge junction. The history of the microplate can be traced back to 1.4 million years ago, as evidenced by the trace of the southern triple junction ridge on the Pacific plate that constitutes the southern boundary of the Galapagos Microplate. At that time, the southern boundary of the microplate was then starting to form by an active hotspot located beneath the East Pacific Rise. The hotspot drifted from the Pacific Plate to the Nazca Plate approximately 1.2 million years ago and a seamount chain began to develop on the Nazca Plate. As the hotspot continued to migrate, rifting of the Nazca Plate developed along its track. This boundary is now known as Dietz Deep Volcanic Ridge, which extends to the northeast and grows at a velocity of 39 mm/year. The Dietz Deep Ridge terminates at the Dietz Deep Basin, an extensional feature with high elevational relief. The seamounts have been volcanically active with ongoing eruptions and continue to uplift the Dietz Deep Volcanic Ridge.

The local shape of the East Pacific Rise has varied with the development of the Galapagos Microplate. Approximately 1.5 million years ago, the East Pacific Rise was convex towards the west. Over time, the axis of the East Pacific Rise straightened and the triple junction began to migrate southward.[2]

Structure edit

The microplate is divided into two regions between north (Northern Galapagos Microplate) and south (Galapagos Microplate). The Galapagos Microplate is bounded by the Dietz volcanic ridge at 1°10'N, south of the Cocos-Nazca Ridge, and the Northern Galapagos Microplate (NGMP) is bounded by the Incipient Ridge at 2°40'N, north of Cocos-Nazca Ridge.[1][3] The westward propagating and slowly diverging Cocos-Nazca Ridge cuts between the two sub-plates toward the East Pacific Rise. However, the tip of Cocos-Nazca Ridge does not fully meet the East Pacific Rise[4] and, in fact, the westerly propagating Cocos-Nazca Ridge generates secondary transient rifts by shear stresses.[5][4] The tip of the Cocos-Nazca ridge has maintained a distance of 50 km from the East Pacific Rise and slightly moved its position into the eastern part of the microplate due to clockwise rotation of the GMP.

Motion of the Galapagos Microplate and Northern Galapagos Microplate edit

Galapagos Microplate edit

Current estimates of the microplate motion may be inaccurate because the limited observational data set is too small for the large vector-based calculation assumptions. That said, the estimated rotational pole is located at 1.4°S, 99.8°W, 400 km southeast from the center of the microplate and 350 km from its closest boundary. Motion is counter-clockwise at 6°/Myr.[3] This rate is in agreement with the northerly strike of the Pacific-Galapagos abyssal hills.

Northern Galapagos Microplate (NGMP) edit

The wedge-shaped Incipient Ridge characterizes the entire motion of the NGMP, as evidenced by recent magmatic activity and magnetic anomaly profiles. The eastern end of the Incipient Ridge is detected cutting through the north–south trending abyssal hills, and both bathymetric and magnetic data have shown recent magmatism along this ridge, supporting the idea that a counterclockwise pivot is located here. The rotation of the NGMP can be understood as clockwise-rotating blocks dragged by shear stresses from plate edges.[6]

References edit

  1. ^ a b Klein, Emily M.; Smith, Deborah K.; Williams, Clare M.; Schouten, Hans (2005). "Counter-rotating microplates at the Galapagos triple junction". Nature. 433 (7028): 855–858. Bibcode:2005Natur.433..855K. doi:10.1038/nature03262. PMID 15729339. S2CID 4424588.
  2. ^ Smith, Deborah K.; Schouten, Hans; Montési, Laurent; Zhu, Wenlu (2013). "The recent history of the Galapagos triple junction preserved on the Pacific plate". Earth and Planetary Science Letters. 371: 6–15. Bibcode:2013E&PSL.371....6S. doi:10.1016/j.epsl.2013.04.018. hdl:1912/6154.
  3. ^ a b Lonsdale, Peter (1988). "Structural Pattern of the Galapagos Microplate and Evolution of the Galapagos Triple Junctions". Journal of Geophysical Research. 93 (B11): 13551–13574. Bibcode:1988JGR....9313551L. doi:10.1029/JB093iB11p13551.
  4. ^ a b Smith, Deborah K.; Schouten, Hans; Zhu, Wen-lu; Montési, Laurent G. J.; Cann, Johnson R. (November 2011). "Distributed deformation ahead of the Cocos-Nazca Rift at the Galapagos triple junction". Geochemistry, Geophysics, Geosystems. 12 (11): Q11003. Bibcode:2011GGG....1211003S. doi:10.1029/2011GC003689. hdl:1912/4937. S2CID 56570936.
  5. ^ Mitchell, Garrett A.; Montési, Laurent G.J.; Zhu, Wenlu; Smith, Deborah K.; Schouten, Hans (July 2011). "Transient rifting north of the Galápagos Triple Junction". Earth and Planetary Science Letters. 307 (3–4): 461–469. Bibcode:2011E&PSL.307..461M. doi:10.1016/j.epsl.2011.05.027.
  6. ^ Schouten, Hans; Klitgord, Kim D.; Gallo, David G. (1993). "Edge-driven microplate kinematics". Journal of Geophysical Research: Solid Earth. 98 (B4): 6689–6701. Bibcode:1993JGR....98.6689S. doi:10.1029/92JB02749.

April 10, 2024
galápagos, microplate, galapagos, microplate, geological, feature, oceanic, crust, located, offshore, west, coast, colombia, collocated, with, galapagos, triple, junction, which, atypical, ridge, ridge, ridge, triple, junction, galapagos, triple, junction, pac. The Galapagos Microplate GMP is a geological feature of the oceanic crust located at 1 50 N offshore of the west coast of Colombia The GMP is collocated with the Galapagos Triple Junction which is an atypical ridge ridge ridge triple junction At the Galapagos Triple Junction the Pacific Plate Cocos Plate and Nazca Plate meet incompletely forming two counter rotating microplates at the junction of the Cocos Nazca Pacific Cocos and Pacific Nazca spreading ridges 1 Contents 1 Geological evolution 2 Structure 3 Motion of the Galapagos Microplate and Northern Galapagos Microplate 3 1 Galapagos Microplate 3 2 Northern Galapagos Microplate NGMP 4 ReferencesGeological evolution editThe entire Galapagos Microplate which covers an area of 13 000 km2 was formed to accommodate the motions of three major moving plates Before the formation of the Galapagos Microplate the Galapagos Triple Junction was a conventional ridge ridge ridge junction The history of the microplate can be traced back to 1 4 million years ago as evidenced by the trace of the southern triple junction ridge on the Pacific plate that constitutes the southern boundary of the Galapagos Microplate At that time the southern boundary of the microplate was then starting to form by an active hotspot located beneath the East Pacific Rise The hotspot drifted from the Pacific Plate to the Nazca Plate approximately 1 2 million years ago and a seamount chain began to develop on the Nazca Plate As the hotspot continued to migrate rifting of the Nazca Plate developed along its track This boundary is now known as Dietz Deep Volcanic Ridge which extends to the northeast and grows at a velocity of 39 mm year The Dietz Deep Ridge terminates at the Dietz Deep Basin an extensional feature with high elevational relief The seamounts have been volcanically active with ongoing eruptions and continue to uplift the Dietz Deep Volcanic Ridge The local shape of the East Pacific Rise has varied with the development of the Galapagos Microplate Approximately 1 5 million years ago the East Pacific Rise was convex towards the west Over time the axis of the East Pacific Rise straightened and the triple junction began to migrate southward 2 Structure editThe microplate is divided into two regions between north Northern Galapagos Microplate and south Galapagos Microplate The Galapagos Microplate is bounded by the Dietz volcanic ridge at 1 10 N south of the Cocos Nazca Ridge and the Northern Galapagos Microplate NGMP is bounded by the Incipient Ridge at 2 40 N north of Cocos Nazca Ridge 1 3 The westward propagating and slowly diverging Cocos Nazca Ridge cuts between the two sub plates toward the East Pacific Rise However the tip of Cocos Nazca Ridge does not fully meet the East Pacific Rise 4 and in fact the westerly propagating Cocos Nazca Ridge generates secondary transient rifts by shear stresses 5 4 The tip of the Cocos Nazca ridge has maintained a distance of 50 km from the East Pacific Rise and slightly moved its position into the eastern part of the microplate due to clockwise rotation of the GMP Motion of the Galapagos Microplate and Northern Galapagos Microplate editGalapagos Microplate edit Current estimates of the microplate motion may be inaccurate because the limited observational data set is too small for the large vector based calculation assumptions That said the estimated rotational pole is located at 1 4 S 99 8 W 400 km southeast from the center of the microplate and 350 km from its closest boundary Motion is counter clockwise at 6 Myr 3 This rate is in agreement with the northerly strike of the Pacific Galapagos abyssal hills Northern Galapagos Microplate NGMP edit The wedge shaped Incipient Ridge characterizes the entire motion of the NGMP as evidenced by recent magmatic activity and magnetic anomaly profiles The eastern end of the Incipient Ridge is detected cutting through the north south trending abyssal hills and both bathymetric and magnetic data have shown recent magmatism along this ridge supporting the idea that a counterclockwise pivot is located here The rotation of the NGMP can be understood as clockwise rotating blocks dragged by shear stresses from plate edges 6 References edit a b Klein Emily M Smith Deborah K Williams Clare M Schouten Hans 2005 Counter rotating microplates at the Galapagos triple junction Nature 433 7028 855 858 Bibcode 2005Natur 433 855K doi 10 1038 nature03262 PMID 15729339 S2CID 4424588 Smith Deborah K Schouten Hans Montesi Laurent Zhu Wenlu 2013 The recent history of the Galapagos triple junction preserved on the Pacific plate Earth and Planetary Science Letters 371 6 15 Bibcode 2013E amp PSL 371 6S doi 10 1016 j epsl 2013 04 018 hdl 1912 6154 a b Lonsdale Peter 1988 Structural Pattern of the Galapagos Microplate and Evolution of the Galapagos Triple Junctions Journal of Geophysical Research 93 B11 13551 13574 Bibcode 1988JGR 9313551L doi 10 1029 JB093iB11p13551 a b Smith Deborah K Schouten Hans Zhu Wen lu Montesi Laurent G J Cann Johnson R November 2011 Distributed deformation ahead of the Cocos Nazca Rift at the Galapagos triple junction Geochemistry Geophysics Geosystems 12 11 Q11003 Bibcode 2011GGG 1211003S doi 10 1029 2011GC003689 hdl 1912 4937 S2CID 56570936 Mitchell Garrett A Montesi Laurent G J Zhu Wenlu Smith Deborah K Schouten Hans July 2011 Transient rifting north of the Galapagos Triple Junction Earth and Planetary Science Letters 307 3 4 461 469 Bibcode 2011E amp PSL 307 461M doi 10 1016 j epsl 2011 05 027 Schouten Hans Klitgord Kim D Gallo David G 1993 Edge driven microplate kinematics Journal of Geophysical Research Solid Earth 98 B4 6689 6701 Bibcode 1993JGR 98 6689S doi 10 1029 92JB02749 Retrieved from https en wikipedia org w index php title Galapagos Microplate amp oldid 1197304824, wikipedia, wiki, book, books, library,

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