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2.3: Convergent Boundaries

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    Convergent boundaries, also called destructive boundaries, are places where two or more plates move toward each other. Convergent boundary movement is divided into two types, subduction and collision, depending on the density of the involved plates. Continental lithosphere is of lower density and thus more buoyant than the underlying asthenosphere. Oceanic lithosphere is denser than continental lithosphere, and, when old and cold, may even be denser than asthenosphere.

    The legend shows shields, platforms, orogens, basins, large igneous provinces, and extended crust.
    Figure \(\PageIndex{1}\): Geologic provinces of Earth. Shields (orange) and platform (pink) comprise cratons, the stable interior of continents. Orogenies are labeled light blue. (By USGS; public domain via Wikimedia Commons.)

    When plates of different densities converge, the higher density plate is pushed beneath the more buoyant plate in a process called subduction. When continental plates converge without subduction occurring, this process is called collision.

    Subduction

    Subduction occurs when a dense oceanic plate meets a more buoyant plate, like a continental plate or warmer/younger oceanic plate, and descends into the mantle [45]. The worldwide average rate of oceanic plate subduction is 25 miles per million years, which is about a half-inch per year [46]. As an oceanic plate descends, it pulls the ocean floor down into a trench. These trenches can be more than twice as deep as the average depth of the adjacent ocean basin, which is usually 3 to 4 km. The Mariana Trench, for example, approaches a staggering 11 km [47].

    Oceanic crust subducting beneath continental crust, forming a trench and creating an accretionary prism. Rising magma above the subducted slab creates a volcanic arc on the continent.
    Figure \(\PageIndex{2}\): Diagram of ocean-continent subduction. (By KDS4444; CC BY-SA 4.0 via Wikimedia Commons.)

    Within the trench, ocean floor sediments are scraped together and compressed between the subducting and overriding plates. This feature is called the accretionary wedge, mélange, or accretionary prism. Fragments of continental material, including microcontinents, riding atop the subducting plate may become sutured to the accretionary wedge and accumulate into a large area of land called a terrane [48]. Vast portions of California are comprised of accreted terranes [49].

    This drawing depicts a microcontinent riding with a subducting plate, and not being subductable, becoming accreted to the melange.
    Figure \(\PageIndex{3}\): Microcontinents can become part of the accretionary prism of a subduction zone. (By Paul Inkenbrandt.)
    Map showing large areas of the western North American continent that are accreted.
    Figure \(\PageIndex{4}\): Accreted terranes of western North America. Everything that is not the “Ancient continental interior (craton)” has been smeared onto the side of the continent by accretion from subduction. (Modified from illustration provided by Oceanus Magazine; original figure by Jack Cook, Woods Hole Oceanographic Institution; adapted by USGS. Used under fair use.)

    When the subducting oceanic plate, or slab, sinks into the mantle, the immense heat and pressure push volatile materials like water and carbon dioxide into an area below the continental plate and above the descending plate called the mantle wedge. The volatiles are released mostly by hydrated minerals that revert to non-hydrated minerals in these higher temperatures and pressure conditions. When mixed with asthenospheric material above the plate, the volatiles lower the melting point of the mantle wedge, and through a process called flux melting it becomes liquid magma. The molten magma is more buoyant than the lithospheric plate above it and migrates to the Earth’s surface where it emerges as volcanism. The resulting volcanoes frequently appear as curved mountain chains, volcanic arcs, due to the curvature of the Earth. Both oceanic and continental plates can contain volcanic arcs.

    How subduction is initiated is still a matter of scientific debate [50]. It is generally accepted that subduction zones start as passive margins, where oceanic and continental plates come together, and then gravity initiates subduction and converts the passive margin into an active one [51]. One hypothesis is gravity pulls the denser oceanic plate down [52] or the plate can start to flow ductility at a low angle [53]. Scientists seeking to answer this question have collected evidence that suggests a new subduction zone is forming off the coast of Portugal [54]. Some scientists have proposed large earthquakes like the 1755 Lisbon earthquake may even have something to do with this process of creating a subduction zone [55], although the evidence is not definitive. Another hypothesis proposes subduction happens at transform boundaries involving plates of different densities [56].

    The epicenter is denoted with a star offshore, near a red jagged line which represents a spreading center.
    Figure \(\PageIndex{5}\): Location of the large (Mw 8.5-9.0) 1755 Lisbon Earthquake. (By USGS; public domain via Wikimedia Commons.)

    Some plate boundaries look like they should be active, but show no evidence of subduction. The oceanic lithospheric plates on either side of the Atlantic Ocean for example, are denser than the underlying asthenosphere and are not subducting beneath the continental plates. One hypothesis is the bond holding the oceanic and continental plates together is stronger than the downward force created by the difference in plate densities.

    Subduction zones are known for having the largest earthquakes and tsunamis; they are the only places with fault surfaces large enough to create magnitude-9 earthquakes. These subduction-zone earthquakes not only are very large but also are very deep. When a subducting slab becomes stuck and cannot descend, a massive amount of energy builds up between the stuck plates. If this energy is not gradually dispersed, it may force the plates to suddenly move and release energy along several hundred kilometers of the subduction zone [57]. Because subduction-zone faults are located on the ocean floor, this massive amount of movement can generate giant tsunamis such as those that followed the 2004 Indian Ocean Earthquake and 2011 Tōhoku Earthquake in Japan.

    Top shows the locations of earthquakes, which are color-coded by depth. Shallow earthquakes are farther from the fault, while deeper earthquakes are behind the fault. Bottom shows a cross-section profile of distance from point A and depth. The earthquakes form an downward arch indicating earthquakes along the descending slab..
    Figure \(\PageIndex{6}\): Earthquakes along the Sunda megathrust subduction zone, along the island of Sumatra, showing the 2006 Mw 9.1-9.3 Indian Ocean earthquake as a star. (By USGS; public domain via Wikimedia Commons.)

    All subduction zones have a forearc basin, a feature of the overriding plate found between the volcanic arc and oceanic trench. The forearc basin experiences a lot of faulting and deformation activity, particularly within the accretionary wedge [58].

    In some subduction zones, tensional forces working on the continental plate create a back-arc basin on the interior side of the volcanic arc. Some scientists have proposed a subduction mechanism called oceanic slab rollback creates extension faults in the overriding plates [59]. In this model, the descending oceanic slab does not slide directly under the overriding plate but instead rolls back, pulling the overlying plate seaward. The continental plate behind the volcanic arc gets stretched like pizza dough until the surface cracks and collapses to form a back-arc basin. If the extension activity is extensive and deep enough, a back-arc basin can develop into a continental rifting zone. These continental divergent boundaries may be less symmetrical than their mid-ocean ridge counterparts [60].

    It shows backarc, volcanic front and forearc.
    Figure \(\PageIndex{7}\): Various parts of a subduction zone. This subduction zone is ocean-ocean subduction, though the same features can apply to continent-ocean subduction. (By MagentaGreen; CC BY-SA 3.0 via Wikimedia Commons.)

    In places where numerous young buoyant oceanic plates are converging and subducting at a relatively high velocity, they may force the overlying continental plate to buckle and crack [61]. This is called back-arc faulting. Extensional back-arc faults pull rocks and chunks of plates apart. Compressional back-arc faults, also known as thrust faults, push them together.

    The dual spines of the Andes Mountain range include a example of compressional thrust faulting. The western spine is part of a volcanic arc. Thrust faults have deformed the non-volcanic eastern spine, pushing rocks and pieces of a continental plate on top of each other.

    There are two styles of thrust fault deformation: thin-skinned faults that occur in superficial rocks lying on top of the continental plate and thick-skinned faults that reach deeper into the crust. The Sevier Orogeny in the western U.S. is a notable thin-skinned type of deformation created during the Cretaceous Period. The Laramide Orogeny, a thick-skinned type of deformation, occurred near the end of and slightly after the Sevier Orogeny in the same region.

    Flat-slab, or shallow, subduction caused the Laramide Orogeny. When the descending slab subducts at a low angle, there is more contact between the slab and the overlying continental plate than in a typical subduction zone. The shallowly-subducting slab pushes against the overriding plate and creates an area of deformation on the overriding plate many kilometers away from the subduction zone [62].

    The subducting plate goes under the overriding plate at a shallow angle.
    Figure \(\PageIndex{8}\): Shallow subduction during the Laramide Orogeny. (By USGS; public domain via Wikimedia Commons.)

    Oceanic-Continental Subduction

    Oceanic-continental subduction occurs when an oceanic plate dives below a continental plate. This convergent boundary has a trench and mantle wedge and frequently, a volcanic arc. Well-known examples of continental volcanic arcs are the Cascade Mountains in the Pacific Northwest [63] and the Western Andes Mountains in South America [64].

    The thinner ocean plate is going under the thicker continental plate.
    Figure \(\PageIndex{9}\): Subduction of an oceanic plate beneath a continental plate, forming a trench and volcanic arc. (By Booyabazooka from USGS; public domain via Wikimedia Commons.)

    Oceanic-Oceanic Subduction

    The boundaries of oceanic-oceanic subduction zones show very different activity from those involving oceanic-continental plates. Since both plates are made of oceanic lithosphere, it is usually the older plate that subducts because it is colder and denser. The volcanism on the overlying oceanic plate may remain hidden underwater.. If the volcanoes rise high enough the reach the ocean surface, the chain of volcanism forms an island arc. Examples of these island arcs include the Aleutian Islands in the northern Pacific Ocean, Lesser Antilles in the Caribbean Sea, and numerous island chains scattered throughout the western Pacific Ocean [65].

    The ocean plate subducts beneath a different ocean plate.
    Figure \(\PageIndex{10}\): Subduction of an oceanic plate beneath another oceanic plate, forming a trench and an island arc. (By USGS; public domain via Wikimedia Commons.)

    Collisions

    When continental plates converge, during the closing of an ocean basin, for example, subduction is not possible between the equally buoyant plates. Instead of one plate descending beneath another, the two masses of continental lithosphere slam together in a process known as collision [66]. Without subduction, there is no magma formation and no volcanism. Collision zones are characterized by tall, non-volcanic mountains; a broad zone of frequent, large earthquakes; and very little volcanism.

    The two continental plates collide. The left plate is shown as subducting due to ancient oceanic crust attached to the continental crust. The collision results in a mountain range.
    Figure \(\PageIndex{11}\): Two continental plates colliding. (By USGS; public domain via Wikimedia Commons.)

    When oceanic crust connected by a passive margin to continental crust completely subducts beneath a continent, an ocean basin closes, and continental collision begins. Eventually, as ocean basins close, continents join together to form a massive accumulation of continents called a supercontinent, a process that has taken place in ~500 million-year-old cycles over Earth’s history.

    The process of collision created Pangea, the supercontinent envisioned by Wegener as the key component of his continental drift hypothesis. Geologists now have evidence that continental plates have been continuously converging into supercontinents and splitting into smaller basin-separated continents throughout Earth’s existence, calling this process the supercontinent cycle, a process that takes place in approximately 500 million years. For example, they estimate Pangea began separating 200 million years ago. Pangea was preceded by earlier supercontinents, one of which being Rodinia, which existed 1.1 billion years ago and started breaking apart 800 million to 600 million years ago.

    Pangaea has a crescent shape.
    Figure \(\PageIndex{12}\): A reconstruction of the supercontinent Pangea, showing approximate positions of modern continents. (By Astroskiandhike; CC BY-SA 4.0 via Wikimedia Commons.)

    A foreland basin is a feature that develops near mountain belts, as the combined mass of the mountains forms a depression in the lithospheric plate. While foreland basins may occur at subduction zones, they are most commonly found at collision boundaries. The Persian Gulf is possibly the best modern example, created entirely by the weight of the nearby Zagros Mountains.

    The mountains are loading the crust down, leading to a depressed basin, which is the Persian Gulf.
    Figure \(\PageIndex{13}\): The tectonics of the Zagros Mountains. Note the Persian Gulf foreland basin. (By Mikenorton; CC BY-SA 3.0 via Wikimedia Commons.)

    If continental and oceanic lithosphere are fused on the same plate, it can partially subduct but its buoyancy prevents it from fully descending. In very rare cases, part of a continental plate may become trapped beneath a descending oceanic plate in a process called obduction [67]. When a portion of the continental crust is driven down into the subduction zone, due to its buoyancy it returns to the surface relatively quickly.

    As pieces of the continental lithosphere break loose and migrate upward through the obduction zone, they bring along bits of the mantle and ocean floor and append them on top of the continental plate. Rocks composed of this mantle and ocean-floor material are called ophiolites and they provide valuable information about the composition of the mantle.

    The rock is cray with many circles inside
    Figure \(\PageIndex{14}\): Pillow lavas, which only form underwater, from an ophiolite in the Apennine Mountains of central Italy. (By Matt Affolter; CC BY-SA 3.0 via Wikimedia Commons.)

    The area of collision-zone deformation and seismic activity usually covers a broader area because the continental lithosphere is plastic and malleable. Unlike subduction-zone earthquakes, which tend to be located along a narrow swath near the convergent boundary, collision-zone earthquakes may occur hundreds of kilometers from the boundary between the plates.

    The Eurasian continent has many examples of collision-zone deformations covering vast areas. The Pyrenees mountains begin in the Iberian Peninsula and cross into France. Also, there are the Alps stretching from Italy to central Europe; the Zagros mountains from Arabia to Iran; and Himalaya mountains from the Indian subcontinent to central Asia.

    Animation of India crashing into Asia over time.
    Animation of India colliding with Asia. (By Raynaldi rji from Tanya Atwater and Peter Molnar; CC BY-SA 4.0 via Wikimedia Commons.)

    References


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