These contrasts often lead to the development of a deep topographic hole on the ridge axis at the intersection of the ridge and transform. Transform faults in the ocean may juxtapose crust with vastly different ages, thickness, temperature, and elevation. Subsidence decreases according to the square root of age. The amount of differential subsidence decreases with increasing distance from the ridge, and the amount of dip-slip motion decreases to near zero after about 60 million years. The motion along the fracture zone is purely dip-slip, due to the different ages of the crust with different subsidence rates on either side of the fracture zone. This dip-slip motion occurs along with the dominant strike-slip motion, recording the sliding of one plate past the other.įracture zones are also called nontransform extension regions. At this point, magmas from the ridge intrude the transform, and the contact becomes an igneous contact.Ĭrossover point, where the transform juxtaposes oceanic lithosphere of the same age formed at the two different ridge segments. Note that the lateral motion between the two segments of the oceanic crust ceases once the opposite ridge segment is passed. The sense of motion on the transform is opposite the apparent offset. Three-dimensional view of a transform fault in the ocean basin, apparently offsetting a segment of the mid-ocean ridge. ^Transform^ Ridge Ridge G Infobase Publishing A component of dip-slip motion occurs all along the transform, except at one critical point, known as the The relative motion includes dip-slip (vertical) motions due to subsidence related to the cooling of the oceanic crust. Transform faults record a very complex history of motion between the two oceanic plates. Rock types along oceanic transforms typically include suites of serpentinite, gabbro, pillow lavas, lherzolites, harzburgites, amphibolite-tectonites, and even mafic granulites. They juxtapose rocks from very different crustal and even mantle horizons, show complex structures, exhibit intense alteration by high-temperature metamorphism, and have numerous igneous intrusions. Transform faults generate very complex geological relationships. The transform and ridge segments preserve an orthogonal relationship in almost all cases, because this geometry creates a least work configuration, creating the shortest length of ridge possible on the spherical Earth. There is typically some vertical motion along this segment of the fracture zone, since the two segments of the plate have different ages, and subside at different rates. After the ridge/transform intersection is passed, the fracture zone juxtaposes two segments of the same plate. Fracture zones are not extensions of the transform faults, and they are no longer considered plate boundaries. At this point, the transform fault is typically intruded by mid-ocean ridge magma, and the apparent extension of the transform, known as a fracture zone, juxtaposes two segments of the same plate that move together horizontally. The two plates then slide past each other along the transform fault between the two ridge segments, until the plate on one side of the transform meets the ridge on the other side of the transform. Magma upwells along the ridge segments, cools and crystallizes, becoming part of one of the diverging plates. Transform plate boundaries in the oceans include the system of ridge-ridge transform faults that are an integral part of the mid-ocean ridge system.
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