The Macquarie Triple Junction is a geologically active tectonic boundary located at 61°30′S161°0′E / 61.500°S 161.000°E [3] at which the historic Indo-Australian Plate, Pacific Plate, and Antarctic Plate collide and interact. The term Triple Junction is given to particular tectonic boundaries at which three separate tectonic plates meet at a specific, singular location. The Macquarie Triple Junction is located on the seafloor of the southern region of the Pacific Ocean, just south of New Zealand. This tectonic boundary was named in respect to the nearby Macquarie Island, which is located southeast of New Zealand.
Our understanding of the evolution of the Macquarie Triple Junction was made possible due to extensive research of the regions tectonic magnetic anomalies as well as local fractures reconstruction. The origin of the Macquarie Triple Junction has been interpreted to have occurred 47.91 Mya (million years ago), based on Anomaly 21. [4] Thorough reconstruction of the Macquarie Triple Junction begins at 33.3 Mya, in respect to Anomaly 13o, and can be simply described as a southeastward migration of approximately 1100 km in respect to the Indo-Australian Plate. [5] The total migration was largely driven by the Australian–Pacific transform boundary.
At 33.3 Mya, the Macquarie Triple Junction was a stable ridge–transform fault–transform fault triple junction. In reference to the Australian Plate, the triple junction moved southeast at an angle of 120° at an approximate rate of 40 km/million years. [5] This trajectory remain relatively constant throughout the Oligocene from 33.3 to 20.1 Mya. During this period of time the Australian-Pacific boundary underwent a transformation from mid-ocean ridge to a strike-slip fault and lastly at 20.1 Mya to a transpression convergent boundary. [5]
Then 10.9 Mya, the Macquarie Triple Junction evolved into a ridge-trench-fault triple junction due to the alteration of the Australian–Pacific Boundary motion. This oblique convergent boundary instigated a clockwise rotation of the Macquarie Ridge Complex forming the Hjort Trench and numerous fracture zones around the Macquarie Ridge. [6] This rotation also transpired into the Macquarie Triple Junction changing its migration path to an angle of 150° and rate of 34 km/million years in reference to the Australian Plate, making the migration direction southward.
Between 5.9 and 2.6 Mya, the Macquarie Triple Junction evolved back into a Ridge–Transform Fault–Transform Fault triple junction as the convergence at the Hjort Trench diminished and Antarctic–Pacific spreading boundary changed back into a transform fault. [5] Elsewhere the Australian Plate before 3 million years ago separated again from the Indian Plate. [7] Already on the Indo-Australian Plate independent rotational motion had developed in a small distal portion of what is now the Australian Plate, and this created a Macquire microplate. [1] This resulted in the current state of the Macquarie Triple Junction and is interpreted as a ridge–fault–fault triple junction that now involves a Macquire microplate rather than the Indo-Australian Plate as was the case before 6 million years ago, Pacific Plate and Antarctic Plate. [2] : 146–149
The Emerald Fracture Zone is the westernmost portion of the Pacific-Antarctic Ridge and is a young leaky transform fault zone no older than 2.197-2.229 Ma. This zone was formed during a change in the Pacific-Antarctic Plate Boundary between 3.4 and 3.86 Ma [8] during a transformation of the Pacific-Antarctic Plate Boundary. This transformation was due to the change in the absolute motion of the Pacific Plate in response to Louisville hotspot activity. The alteration of the Pacific Plate ‘s motion caused a left-lateral strike-slip fault to form at the Pacific-Antarctic Boundary. This strike-slip fault is located near the triple junction along a sharp bend in the westernmost region of the Pacific-Antarctic Boundary. This sharp bend is now the locality of the Emerald Fracture Zone formed from a release bend configuration as seen in transtension.
The Southeast Indian Ridge is the divergent boundary that separates the Indo-Australian and Antarctic Plates. This boundary has experienced a vast right-lateral transform fault called the Balleny Fault Zone, which is also thought to be caused in response to the formation of the Emerald Fracture Zone. [5] This large offset in the Southeast Indian Ridge is thought to have produced a significant difference in crustal thickness within the Australian Plate influencing the Hjort Trench formation.
The Hjort Trench is the southernmost portion of the Macquarie Ridge Complex and has been identified as an oceanic-oceanic subduction zone. This trench is found in a region of diagonal convergence produced by the transform fault evolution of the Emerald Fracture Zone. [9] Due to these transpressive plate movements this trench has frequent seismic events generally less than 20 km depth, [6] which suggest underthrusting of the Indo-Australian Plate underneath the Pacific Plate. This region of underthrusting may eventually evolve into a self-sustaining subduction zone, though the Hjort Trench is thought to be an example of an oceanic subduction zone initiated in response to transform fault development. [10]
The understanding of the Macquarie Triple Junction is primarily known due to the study of the seismicity, gravitational, magnetic and bathymetric data of the region. Initial studies took place during the early 1970s by the Eltanin Cruises, which took bathymetric and magnetic tracks in order to interpret the general sea floor topography and sea-floor spreading rates. Additional surveys have been taken during 1988–1991 by multiple cruises of the OGS-Explora. These surveys consist of approximately 6300 km the regions seismicity, gravitational signatures, and additional magnetic and bathymetric surveys, significantly contributing to the understanding of the Macquarie Triple Junction. [6] From analysis of the data obtained from the OGS-Explora, a major change in the Pacific-Antarctic plate motion has been interpreted, instigating the compressional region of the Macquarie Ridge. High-resolution bathymetric and magnetic data were acquired by R/V Araon and M/V L’Astrolabe cruises along the axis of the two easternmost Southeast Indian Ridge segments which by 2017 had confirmed the recent existence of a Macquire microplate. [1] In 2017 and 2019 R/V Explora and R/V Laura Bassi undertook multibeam and magnetic surveys focused on the three plate boundaries meeting at the Macquarie Triple Junction. [2] : 147
The Australian Plate (or Indo-Australian Plate) and Antarctic Plate Boundary is an active divergent boundary known as the Southeast Indian Ridge. The Southeast Indian Ridge ranges approximately 2000 kilometers across the southern region of the Indian Ocean. The Southeast Indian Ridge has a complex driving force which is due to the interaction of the Amsterdam-St. Paul Plateau, a developed hot spot in the western portion of the Southeast Indian Ridge, and the mid-oceanic ridge (MOR). [11] The Amsterdam-St. Paul Plateau along with the Southeast Indian Ridge produce new oceanic crust further separating the Indo-Australian and Antarctic plates at an intermediate tectonic rate of 65 mm/yr. [12]
The Pacific-Antarctic Plate Boundary is another active divergent boundary known as the Pacific-Antarctic Ridge(PAR). The Pacific-Antarctic Ridge is the southwest region of the East Pacific Rise, the mid-oceanic ridge located at the base of the Pacific Ocean. The PAR is divergent boundary [13] driven by the interaction of a MOR and deep mantle plumes [14] located in the eastern portion of the East Pacific Rise. These deep mantle plumes however, have given the Pacific Plate a left lateral force vector creating a transform boundary in the western Pacific-Antarctic Plate Boundary in the vicinity of the Macquarie Triple Junction, forming the Emerald Fracture Zone.
The Australian Plate (previous to 3 million years ago the Indo-Australian Plate) and Pacific Plate boundary is the most complex boundary of the Macquarie Triple Junction region, due to the unique collision of the two plates creating two convergent boundaries separated by a transform boundary. There is increasing evidence that the last 6.4 million years of this evolution at the triple junction has been associated with the creation of a separate microplate, the Macquarie Plate. [1] [2] : 146–149 The assumption in models of this microplate's existence not only allows a much better fit to historic data relevant to the triple junction, it fits with more recent data for what was an understudied area at the time this triple junction's evolution was first studied. [2] : 146–147
The Puysegur Trench, which includes the Fjord Trench, is the southern region of the boundary closest to the Macquarie Triple Junction. The Puysegur Trench formed as the Australian Plate subducted beneath the Pacific plate. The Puysegur Trench ranges approximately 800 kilometers in length, from the most southern tip of the New Zealand Islands to the Macquarie Triple Junction. The Puysegur Trench makes contact with the Macquarie Fault Zone, which is associated with the Alpine Fault. The Alpine Fault is the right-lateral transform fault boundary separating the Puysegur Trench and the northern Kermadec Trench. [15] The Alpine Fault runs through the majority of the southern island of New Zealand and is associated with New Zealand's frequent and intense earthquake history. The last major region of the Australian Plate and Pacific Plate Boundary is the Kermadec-Tonga subduction zone at which the Pacific Plate is subducted beneath the Australian Plate, in opposition of the Puysegur Trench. This convergent boundary has a rate of subduction of approximately 5.5-7.4 cm/yr. [15]
The Nazca Plate or Nasca Plate, named after the Nazca region of southern Peru, is an oceanic tectonic plate in the eastern Pacific Ocean basin off the west coast of South America. The ongoing subduction, along the Peru–Chile Trench, of the Nazca Plate under the South American Plate is largely responsible for the Andean orogeny. The Nazca Plate is bounded on the west by the Pacific Plate and to the south by the Antarctic Plate through the East Pacific Rise and the Chile Rise respectively. The movement of the Nazca Plate over several hotspots has created some volcanic islands as well as east–west running seamount chains that subduct under South America. Nazca is a relatively young plate both in terms of the age of its rocks and its existence as an independent plate having been formed from the break-up of the Farallon Plate about 23 million years ago. The oldest rocks of the plate are about 50 million years old.
The Pacific Plate is an oceanic tectonic plate that lies beneath the Pacific Ocean. At 103 million km2 (40 million sq mi), it is the largest tectonic plate.
The Explorer Plate is an oceanic tectonic plate beneath the Pacific Ocean off the west coast of Vancouver Island, Canada, which is partially subducted under the North American Plate. Along with the Juan de Fuca Plate and Gorda Plate, the Explorer Plate is a remnant of the ancient Farallon Plate, which has been subducted under the North American Plate. The Explorer Plate separated from the Juan de Fuca Plate roughly 4 million years ago. In its smoother, southern half, the average depth of the Explorer plate is roughly 2,400 metres (7,900 ft) and rises up in its northern half to a highly variable basin between 1,400 metres (4,600 ft) and 2,200 metres (7,200 ft) in depth.
The Australian Plate is a major tectonic plate in the eastern and, largely, southern hemispheres. Originally a part of the ancient continent of Gondwana, Australia remained connected to India and Antarctica until approximately 100 million years ago when India broke away and began moving north. Australia and Antarctica had begun rifting by 96 million years ago and completely separated a while after this, some believing as recently as 45 million years ago, but most accepting presently that this had occurred by 60 million years ago.
The Burma Plate is a minor tectonic plate or microplate located in Southeast Asia, sometimes considered a part of the larger Eurasian Plate. The Andaman Islands, Nicobar Islands, and northwestern Sumatra are located on the plate. This island arc separates the Andaman Sea from the main Indian Ocean to the west.
The Scotia Plate is a minor tectonic plate on the edge of the South Atlantic and Southern oceans. Thought to have formed during the early Eocene with the opening of the Drake Passage that separates Antarctica and South America, it is a minor plate whose movement is largely controlled by the two major plates that surround it: the Antarctic Plate and the South American Plate. The Scotia Plate takes its name from the steam yacht Scotia of the Scottish National Antarctic Expedition (1902–04), the expedition that made the first bathymetric study of the region.
A triple junction is the point where the boundaries of three tectonic plates meet. At the triple junction each of the three boundaries will be one of three types – a ridge (R), trench (T) or transform fault (F) – and triple junctions can be described according to the types of plate margin that meet at them. Of the ten possible types of triple junctions only a few are stable through time. The meeting of four or more plates is also theoretically possible but junctions will only exist instantaneously.
The Phoenix Plate was a tectonic plate that existed during the early Paleozoic through late Cenozoic time. It formed a triple junction with the Izanagi and Farallon plates in the Panthalassa Ocean as early as 410 million years ago, during which time the Phoenix Plate was subducting under eastern Gondwana.
The South American–Antarctic Ridge or simply American-Antarctic Ridge is the tectonic spreading center between the South American Plate and the Antarctic Plate. It runs along the sea-floor from the Bouvet Triple Junction in the South Atlantic Ocean south-westward to a major transform fault boundary east of the South Sandwich Islands. Near the Bouvet Triple Junction the spreading half rate is 9 mm/a (0.35 in/year), which is slow, and the SAAR has the rough topography characteristic of slow-spreading ridges.
The 1,600 kilometres (990 mi) long Macquarie Fault Zone is a major right lateral-moving transform fault along the seafloor of the south Pacific Ocean which runs from New Zealand southwestward towards the Macquarie Triple Junction. It is also the tectonic plate boundary between the Australian Plate to the northwest and the Pacific Plate to the southeast. As such it is a region of high seismic activity and recorded the largest strike-slip event on record up to May 23, 1989, of at least Mw8.0
This is a list of articles related to plate tectonics and tectonic plates.
The Emerald Fracture Zone is an undersea fracture zone running the distance from the southwest corner of the Campbell Plateau to the northern tip of Iselin Bank. The name was proposed by Dr. Steven C. Cande of the Scripps Institution of Oceanography for the vessel Emerald, which traversed this region in 1821, and was approved by the Advisory Committee for Undersea Features in June 1997. The Emerald Basin to its north west was named from the same source. Some have restricted the name to the southern east west orientated transform fault zone but the north south orientated faults that define the eastern boundary of the Emerald Basin are generally included in the literature.
The Pacific Ocean evolved in the Mesozoic from the Panthalassic Ocean, which had formed when Rodinia rifted apart around 750 Ma. The first ocean floor which is part of the current Pacific Plate began 160 Ma to the west of the central Pacific and subsequently developed into the largest oceanic plate on Earth.
The Hjort Trench is a linear topographic depression south of Macquarie Island in the southwest Pacific Ocean. Geologically, the depression is considered to be the seafloor expression of an ocean-ocean subduction zone, where the Australian plate is thrusting beneath the Pacific Plate. As the southernmost portion of the Macquarie Ridge Complex, the Hjort Trench lies in an area of diagonal convergence produced by the transform fault evolution of the Emerald Fracture Zone. Frequent seismic events, most less than 20 km (12 mi) deep, characterize the transpression along this plate boundary.
The Chile Ridge, also known as the Chile Rise, is a submarine oceanic ridge formed by the divergent plate boundary between the Nazca Plate and the Antarctic Plate. It extends from the triple junction of the Nazca, Pacific, and Antarctic plates to the Southern coast of Chile. The Chile Ridge is easy to recognize on the map, as the ridge is divided into several segmented fracture zones which are perpendicular to the ridge segments, showing an orthogonal shape toward the spreading direction. The total length of the ridge segments is about 550–600 km.
In the early morning hours of Friday 24 December 2004, a very large magnitude 8.1 earthquake struck a remote area of the southern Tasman Sea. Its epicentre was located roughly 360 km (224 mi) northwest of the Auckland Islands of New Zealand, and roughly 600 km (373 mi) north of Macquarie Island of Australia. Shaking was reportedly felt as far as Tasmania and the South Island. The event was a complex intraplate earthquake within the Australian Plate, which generated a small tsunami.
The Hunter Fracture Zone is a sinistral (left-lateral) transform faulting fracture zone, that to its south is part of a triple junction with the New Hebrides Trench, and the North Fiji Basin Central Spreading Ridge. The Hunter Fracture Zone, with the Hunter Ridge, an area with recent volcanic activity to its north, is the southern boundary of the North Fiji Basin. This boundary area in the south-western part of the Hunter Fracture Zone is associated with hot subduction, and a unique range of volcanic geochemistry.
The Vanuatu subduction zone is currently one of the most active subduction zones on earth, producing great earthquakes, with potential for tsunami hazard to all coastlines of the Pacific ocean. There are active volcanoes associated with arc volcanism.