All at Sea | ScienceGate

Transforms are forever

10.5194/egusphere-egu21-12200 ◽

2021 ◽

Author(s):

Paola Vannucchi ◽

David Iacopini ◽

Jason P. Morgan

Keyword(s):

Fluid Flow ◽

Seismic Activity ◽

Plate Tectonics ◽

Driving Forces ◽

Permanent Deformation ◽

Oceanic Lithosphere ◽

Ocean Floor ◽

Spreading Center ◽

Transform Faults ◽

Recent Earthquakes

According to Plate Tectonics, fracture zones (FZs) are born at Transform Faults (TFs), which leave behind "inactive" FZs traces as scars on the seafloor that reflect their initial use as one side of a strike-slip transform fault. FZs were originally thought to "heal" as the oceanic lithosphere cooled and strengthened with time. However, the occurrence of recent earthquakes reveals that FZs can be associated with significant seismic activity (for example during the recent Mw 8.6 2012 EQ offshore Sumatra and Mw 7.9 2018 EQ offshore SE Kodiak), and also with permanent deformation that occurs well after passage through the TF.The TF at the spreading center is known to be accompanied by the formation of the transform valley which exposes serpentinized peridotite to the ocean floor. Valley relief itself can drive fluid flow that promotes continued serpentinization, and also cooling- and volume-change-linked stress variations. Off-axis seismicity suggests that FZs remain weaker that neighbouring oceanic lithosphere. The transform valley relief in general persists as a fracture zone valley that itself can continue to be a major drive of fluid flow even in the &#8220;healed&#8221; oceanic lithosphere. After reviewing evidence for FZ activity on (normal) ocean floor we will focus on the long-lived impact of FZs at continental margins. Offshore/onshore evidence of ongoing deformation at FZs is observed through seismic activity at both the western Brazilian and eastern Ghana-C&#244;te d&#8217;Ivoire ends of the Romanche FZ. The western Brazil end is also characterized by recent folding and faulting, both offshore across the FZ, and onshore co-linearly with FZ extensions into the continent. Seismic activity in continental Brazil is focused where the FZ intersects the continental margin. This activity suggests that FZs remain as permanent weak lithospheric heterogeneities that are able to store elastic strain.The reasons why FZs remain active are still poorly understood. Possible causes include i) effects of serpentinization that occurs both in the TF and in the FZ through hydrothermal fluid/mantle interaction, ii) thermal stress, iii) changing tectonic stresses related to plate driving forces.

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Initiation of a Proto-transform Fault Prior to Seafloor Spreading

10.26686/wgtn.13089095 ◽

2020 ◽

Author(s):

Finnigan Illsley-Kemp ◽

JM Bull ◽

D Keir ◽

T Gerya ◽

C Pagli ◽

...

Keyword(s):

Plate Tectonics ◽

Seafloor Spreading ◽

Continental Rift ◽

Formation Mechanisms ◽

Transform Fault ◽

Transform Faults ◽

Local Seismicity ◽

Ocean Ridges ◽

Rifted Margins ◽

Direct Observations

©2018. The Authors. Transform faults are a fundamental tenet of plate tectonics, connecting offset extensional segments of mid-ocean ridges in ocean basins worldwide. The current consensus is that oceanic transform faults initiate after the onset of seafloor spreading. However, this inference has been difficult to test given the lack of direct observations of transform fault formation. Here we integrate evidence from surface faults, geodetic measurements, local seismicity, and numerical modeling of the subaerial Afar continental rift and show that a proto-transform fault is initiating during the final stages of continental breakup. This is the first direct observation of proto-transform fault initiation in a continental rift and sheds unprecedented light on their formation mechanisms. We demonstrate that they can initiate during late-stage continental rifting, earlier in the rifting cycle than previously thought. Future studies of volcanic rifted margins cannot assume that oceanic transform faults initiated after the onset of seafloor spreading.

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Probably the Best Theory on Earth

10.1093/oso/9780198717867.003.0002 ◽

2018 ◽

Author(s):

Roy Livermore

Keyword(s):

Geomagnetic Field ◽

Convincing Evidence ◽

Ocean Floor ◽

Bar Code ◽

Sea Floor ◽

Ocean Ridges ◽

Sea Bed ◽

The Pacific ◽

Sea Floor Spreading

The magnetic bar-code on the ocean floor provides convincing evidence of moving continents, yet, as with the discovery of the structure of DNA, few are convinced—at first. Drilling in the deep oceans and geochemical work at mid-ocean ridges provides further evidence in support of the Vine–Matthews Hypothesis. Application of the hypothesis to data collected in the Pacific and Atlantic Oceans establishes sea-floor spreading as the process that creates new oceans and, in conjunction with reversals of the geomagnetic field, stamps the bar-code into the rocks beneath the sea bed.

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MORGEN – The Mid Ocean Ridge GENerating algorithm

10.5194/egusphere-egu21-9494 ◽

2021 ◽

Author(s):

Thomas van der Linden ◽

Douwe van Hinsbergen

Keyword(s):

Conceptual Knowledge ◽

Smooth Curve ◽

Weddell Sea ◽

Plate Boundaries ◽

Plate Tectonic ◽

Transform Faults ◽

Ocean Ridges ◽

Euler Pole ◽

Mid Ocean Ridge ◽

Ocean Ridge

Paleo-digital elevation models (paleoDEM) based on plate tectonic and paleogeographic reconstructions use age grids of ocean floor to determine ocean bathymetry. In recent years, such age grids have also been developed for now-subducted oceans from the far geological past, as far back as the Neoproterozoic, using geology and paleomagnetism-based estimates of ocean opening. In such reconstructions, mid ocean ridges are drawn based on estimated Euler poles and rotations, and conceptual knowledge on the geometry consisting of spreading ridges and transform faults.Current procedures to draw mid ocean ridges in plate tectonic reconstructions are laborious, as new ridges are drawn every time the Euler pole location changes. Fortunately this is also a task that can be automated. We have written an algorithm using pyGPlates that takes as input a smooth curve at the approximate position of the reconstructed mid ocean ridge at the moment of its formation, and then calculates spreading and transform segments according to their typical geometries in modern oceans, assuming symmetric spreading. The algorithm allows gradual readjustment of ridge orientations upon Euler pole changes comparable to documented cases in the modern oceans (e.g., in the Weddell Sea). The algorithm also contains modules that can convert the calculated mid ocean ridges with other plate boundaries to boundary topologies &#8211; which can be used as input for the recently published TracerTectonics algorithm, produce isochrons which can be converted to age grids, check for subduction of isochrons and subsequently create bathymetry grids. We illustrate the use of the MORGEN algorithm with recently published reconstructions of subducted, as well as future oceans.

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The structure of the oceanic lithosphere

Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences ◽

10.1098/rsta.1971.0016 ◽

1971 ◽

Vol 268 (1192) ◽

pp. 619-619

Keyword(s):

Oceanic Crust ◽

Upper Mantle ◽

Oceanic Lithosphere ◽

Ocean Floor ◽

Mass Motion ◽

Sea Floor ◽

Ocean Ridges ◽

Velocity Gradients ◽

The Earth ◽

Sea Floor Spreading

Sea-floor spreading requires that new ocean floor be generated at mid-ocean ridges and that along with the underlying oceanic crust it move laterally away from its site of generation. In so far as it is unlikely that the 5 km thick oceanic crust moves independently of the underlying upper mantle, the horizontal mass motion associated with spreading extends at least some way into the mantle. The lithosphere is the crust and that part of the upper mantle to which it is mechanically coupled; together they form the brittle and relatively ‘strong’ outermost part of the Earth; velocity gradients within the lithosphere are negligible.

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Semibrittle seismic deformation in high-temperature mantle mylonite shear zone along the Romanche transform fault

Science Advances ◽

10.1126/sciadv.abf3388 ◽

2021 ◽

Vol 7 (15) ◽

pp. eabf3388

Author(s):

Zhiteng Yu ◽

Satish C. Singh ◽

Emma P. M. Gregory ◽

Marcia Maia ◽

Zhikai Wang ◽

...

Keyword(s):

High Temperature ◽

Plate Tectonics ◽

Thermal Structure ◽

Depth Range ◽

Transform Fault ◽

Equatorial Atlantic ◽

Transform Faults ◽

Ocean Ridges ◽

Equatorial Atlantic Ocean ◽

Large Earthquakes

Oceanic transform faults, a key element of plate tectonics, represent the first-order discontinuities along mid-ocean ridges, host large earthquakes, and induce extreme thermal gradients in lithosphere. However, the thermal structure along transform faults and its effects on earthquake generation are poorly understood. Here we report the presence of a 10- to 15-kilometer-thick in-depth band of microseismicity in 10 to 34 kilometer depth range associated with a high-temperature (700° to 900°C) mantle below the brittle lithosphere along the Romanche mega transform fault in the equatorial Atlantic Ocean. The occurrence of the shallow 2016 moment magnitude 7.1 supershear rupture earthquake and these deep microearthquakes indicate that although large earthquakes occur in the upper brittle lithosphere, a substantial amount of deformation is accommodated in the semibrittle mylonitic mantle that resides at depths below the 600°C isotherm. We also observe a rapid westward deepening of this band of seismicity indicating a strong lateral heterogeneity.

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Energy of plate tectonics calculation and projection

Solid Earth Discussions ◽

10.5194/sed-5-135-2013 ◽

2013 ◽

Vol 5 (1) ◽

pp. 135-161

Author(s):

N. H. Swedan

Keyword(s):

Climate Change ◽

Surface Temperature ◽

Latent Heat ◽

Temperature Rise ◽

Plate Tectonics ◽

Ocean Floor ◽

Sea Floor ◽

Midocean Ridges ◽

Latent Heat Of Melting ◽

Sea Floor Spreading

Abstract. Mathematics and observations suggest that the energy of the geological activities resulting from plate tectonics is equal to the latent heat of melting, calculated at mantle's pressure, of the new ocean crust created at midocean ridges following sea floor spreading. This energy varies with the temperature of ocean floor, which is correlated with surface temperature. The objective of this manuscript is to calculate the force that drives plate tectonics, estimate the energy released, verify the calculations based on experiments and observations, and project the increase of geological activities with surface temperature rise caused by climate change.

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Initiation of a Proto-transform Fault Prior to Seafloor Spreading

10.26686/wgtn.13089095.v1 ◽

2020 ◽

Author(s):

Finnigan Illsley-Kemp ◽

JM Bull ◽

D Keir ◽

T Gerya ◽

C Pagli ◽

...

Keyword(s):

Plate Tectonics ◽

Seafloor Spreading ◽

Continental Rift ◽

Formation Mechanisms ◽

Transform Fault ◽

Transform Faults ◽

Local Seismicity ◽

Ocean Ridges ◽

Rifted Margins ◽

Direct Observations

©2018. The Authors. Transform faults are a fundamental tenet of plate tectonics, connecting offset extensional segments of mid-ocean ridges in ocean basins worldwide. The current consensus is that oceanic transform faults initiate after the onset of seafloor spreading. However, this inference has been difficult to test given the lack of direct observations of transform fault formation. Here we integrate evidence from surface faults, geodetic measurements, local seismicity, and numerical modeling of the subaerial Afar continental rift and show that a proto-transform fault is initiating during the final stages of continental breakup. This is the first direct observation of proto-transform fault initiation in a continental rift and sheds unprecedented light on their formation mechanisms. We demonstrate that they can initiate during late-stage continental rifting, earlier in the rifting cycle than previously thought. Future studies of volcanic rifted margins cannot assume that oceanic transform faults initiated after the onset of seafloor spreading.

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On crustal plates

Bulletin of the Seismological Society of America ◽

10.1785/bssa0650051495 ◽

1975 ◽

Vol 65 (5) ◽

pp. 1495-1500

Author(s):

Don Tocher

Keyword(s):

Plate Tectonics ◽

Seismic Waves ◽

Continental Drift ◽

Active Regions ◽

Continental Margins ◽

Island Arcs ◽

Low Velocity ◽

Transform Faults ◽

Sea Floor Spreading ◽

Velocity Layer

Abstract During the decade just past, developments in Seismology have played an active and central role in the development of the concept of Plate Tectonics. Observational Seismology has provided support for and verification of a number of the dynamic aspects of the hypotheses of continental drift, sea-floor spreading, transform faults and the underthrusting of the lithosphere at island arcs and some continental margins. Those types of seismological evidence which bear on the question of the thickness of the lithosphere are either indirect or circumstantial, or both. As early as 1926, Gutenberg postulated the existence of a layer at a depth of 80 to 150 or 200 km, probably worldwide in extent, in which the velocities of seismic waves are slightly lower than in the immediately overlying layers. Some plate tectonics workers equate this low-velocity layer to the relatively-weak asthenosphere required by Plate Tectonics to underlie the stronger, more brittle lithosphere. In this review, several lines of evidence are marshalled in support of a plate model of the continental crust in seismically active regions in which a layer of decoupling of an upper, lithospheric layer from the weaker substrate may lie in the crust itself at a depth of perhaps 10 to 15 km.

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Marie Tharp: Seafloor mapping and ocean plate tectonics

10.5194/egusphere-egu2020-12641 ◽

2020 ◽

Author(s):

Mathilde Cannat ◽

Deborah Smith ◽

Daniel Fornari ◽

Vicki Ferrini ◽

Javier Escartin

Keyword(s):

Plate Tectonics ◽

Essential Element ◽

Central Valley ◽

Fracture Zones ◽

Transform Faults ◽

Seafloor Mapping ◽

Mid Ocean Ridge ◽

The 1960S ◽

Ocean Ridge ◽

Central Atlantic

The pioneering&#160;seafloor mapping by Marie Tharp&#160;played a key role in the acceptance of the plate tectonic theory. Her physiographic maps,&#160;&#160;published with Bruce Heezen,&#160;&#160;covered&#160;the&#160;Earth&#8217;s oceans and revealed with astonishing accuracy the submarine landscape. She exposed the full extent of the global mid-ocean ridge system, documented features such as seamounts and volcanic chains, trenches, and transform faults. Marie Tharp co-authored the first papers describing the major fracture zones in the Central Atlantic (Chain, Romanche, Vema).&#160;In 1952, she also discovered that the Atlantic ridge has a central valley (the axial valley), and convinced her colleague Bruce Heezen that it, which corresponds to sustained seismicity (highlighted by other researchers at the same time thanks to the worldwide networking of seismological stations), is a rift that separates the eastern and western provinces of the Atlantic Ocean. Tharp and Heezen were not yet talking about plate tectonics at this time. But when, at the beginning of the 1960s, the first magnetic anomaly maps showed that the oceans were "young", and that the age of the seabed increased with the distance from the ridges, their physiographic map became an essential element in understanding the role that these ridges play, as well as the distribution of the main current terrestrial plates. In this poster, we present original maps and sketches that document this key contribution to the understanding of the Earth's tectonics.

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