Seismic Structure of the St. Paul Fracture Zone and Late Cretaceous to Mid Eocene Oceanic Crust in the Equatorial Atlantic Ocean Near 18°W

Growe, Kevin; Grevemeyer, Ingo; Singh, S. C.; Marjanović, M.; Gregory, Emma P. M.; Papenberg, Cord; Vaddineni, Venkata; Peña, L. Gómez de la; Wang, Zhikai

doi:10.1029/2021jb022456

Cited by 13 publications

(20 citation statements)

References 92 publications

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“…Velocities as slow as 7.2 km s -1 observed beneath the Moho in such segments indicate extensive hydrous alteration within the incoming plate. The FZs and NTOs themselves do not stand out from the structure of the surrounding crust, but instead have a structure similar to neighbouring segments, consistent with other recent work in the equatorial Atlantic (Growe et al, 2021;Marjanović et al, 2020).…”

Section: ) Tectonic Settingsupporting

confidence: 89%

“…By comparing the velocity structures from the two VoiLA profiles (Figure 4), we find section 1 (which lies closest to the 15-20 FZ) strongly correlates with the structure of the ends of magmatically robust spreading segments observed on line 2/3, and section 2 as from a central portion of the segment where melt is more focused. Modest crustal thinning towards the segment ends is consistent with trends observed both within the magmatic spreading segments of Line 2/3 and studies of crustal thickness trends within magmatic segments at the MAR (Growe et al, 2021;Lin & Phipps-Morgan, 1992;Lin et al, 1990;Marjanović et al, 2020;Wang et al, 2015). The interpreted boundary between sections 1 and 2 occurs ~ 75 km from the mapped 15-20 FZ, which is further than any of the segment ends in the Line 2/3 survey area, but both the segment width and FZ offsets are significantly larger than observed in the Davy et al ( 2020) study.…”

Section: 1) Crustal Accretion Variationssupporting

confidence: 85%

“…Recent wide‐angle studies from the Atlantic, have found the structure (and thus degree of alteration) at FZs to be highly dependent on the mechanism of crustal accretion in the adjacent ridge segments. Studies at the Marathon (Davy et al., 2020), St. Paul (Growe et al., 2021) and Chain (Marjanović et al., 2020) FZs, flanked by magmatically robust ridge segments found little structural variation and little indication of elevated hydration, while at the Romanche transform fault, flanked to the south by a tectonically accreting ridge segment Gregory et al. (2021) observed up to 30% serpentinization of the upper mantle (and potentially up to 80% within the fault zone itself).…”

Section: Discussionmentioning

confidence: 99%

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The Role of Crustal Accretion Variations in Determining Slab Hydration at an Atlantic Subduction Zone

2022

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We present a 2D P‐wave velocity model from the outer rise region of the Lesser Antilles island arc, the first wide‐angle seismic study of outer rise processes at an Atlantic subduction zone. The survey consists of 46 OBS receivers over a 174 km profile with velocities resolved to 15 km below top basement. The final velocity model, produced through tomographic inversion, shows a clear decrease in the velocity of the lower crust and upper mantle of the incoming plate as it approaches the trench. We attribute this drop to outer rise bend‐related hydration, similar to Pacific cases, but superimposed on spatial variations in hydration generated at the slow‐spreading ridge axis. In thin, tectonically controlled crust formed under magma‐poor spreading conditions the superposition of these sources of hydration results in compressional velocities as low as 6.5 km s−1 beneath the PmP reflector. In contrast, segments of crust interpreted as having formed under magma‐rich conditions show velocity reductions and inferred hydrous alteration more like that observed in the Pacific. Hence, variations in the style of crustal accretion, which is observed on 50–100 km length scales both along and across isochrons, is a primary control over the distribution of water within the slab at Atlantic subduction systems. This heterogeneous pattern of water storage within the slab is likely further complicated by along strike variations in outer rise bending, subducting fracture zones and deformation at segment ends and may have important implications for our understanding of long‐term patterns of hazard at Atlantic subduction systems.

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Section: ) Tectonic Settingsupporting

confidence: 89%

Section: 1) Crustal Accretion Variationssupporting

confidence: 85%

Section: Discussionmentioning

confidence: 99%

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The Role of Crustal Accretion Variations in Determining Slab Hydration at an Atlantic Subduction Zone

2022

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“…The presence of thin lithosphere would have a significant effect on the geodynamics of the ridge-transform system. It might account for some recent observations of thick magmatic crust at oceanic TF 5 and FZs 31 , 32 in the equatorial Atlantic Ocean. Wide-spread volcanism is generally absent along oceanic TFs due to the cold edge effect 33 .…”

Section: Effects Of Lithospheric Thinning At Oceanic Transform Faultsmentioning

confidence: 68%

Deep hydration and lithospheric thinning at oceanic transform plate boundaries

et al. 2022

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Transform plate boundaries, one of the key elements of plate tectonics, accommodate lateral motions and produce large earthquakes, but their nature at depth remains enigmatic. Using ultra-long offset seismic data, here we report the presence of a low-velocity anomaly extending down to ~60 km depth beneath the Romanche transform fault in the equatorial Atlantic Ocean. Our result indicates the presence of deep penetration of water leading to extensive serpentinization down to 16 km, followed by a shear mylonite zone down to 32 km over a low-temperature water induced-melting zone, elevating the lithosphere-asthenosphere boundary and hence thinning the lithosphere signi cantly beneath the transform fault. The presence of a thinned lithosphere and the melt underneath could lead to volcanism, migration and mixing of the water-induced melt with the high-temperature melt beneath the ridge axis, and small-scale convections beneath transform boundaries. Hence, a thinned lithosphere will have a major impact on the dynamics of ridge-transform system, and will in uence the evolution of fracture zones and oceanic lithosphere.

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“…2a ). The St. Paul TF system encompasses four TFs interrupted by three intra-transform ridge segments, generating a total offset of ~600 km 43 . Away from its eastern ridge-transform intersections (RTIs), the traces of the four TFs persist up to ~20 Ma old seafloor and then only two traces of the TFs can be identified on the older seafloor 44 .…”

Section: Introductionmentioning

confidence: 99%

Seismic evidence for uniform crustal accretion along slow-spreading ridges in the equatorial Atlantic Ocean

Wang

Singh

2022

Nat Commun

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The crustal accretion along mid-ocean ridges is known to be spreading-rate dependent. Along fast-spreading ridges, two-dimensional sheet-like mantle upwelling creates relatively uniform crust. In contrast, the crust formed along slow-spreading ridges shows large along-axis thickness variations with thicker crust at segment centres, which is hypothesised to be due a three-dimensional plume-like mantle upwelling or due to focused melt migration to segment centres. Using wide-angle seismic data acquired from the equatorial Atlantic Ocean, here we show that the crustal thickness is nearly uniform (~5.5 km) across five crustal segments for crust formed at the slow-spreading Mid-Atlantic Ridge with age varying from 8 to 70 Ma. The crustal velocities indicate that this crust is predominantly of magmatic origin. We suggest that this uniform magmatic crustal accretion is due to a two-dimensional sheet-like mantle upwelling facilitated by the long-offset transform faults in the equatorial Atlantic region and the presence of a high concentration of volatiles in the primitive melt in the mantle.

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Seismic Structure of the St. Paul Fracture Zone and Late Cretaceous to Mid Eocene Oceanic Crust in the Equatorial Atlantic Ocean Near 18°W

Cited by 13 publications

References 92 publications

The Role of Crustal Accretion Variations in Determining Slab Hydration at an Atlantic Subduction Zone

The Role of Crustal Accretion Variations in Determining Slab Hydration at an Atlantic Subduction Zone

Deep hydration and lithospheric thinning at oceanic transform plate boundaries

Seismic evidence for uniform crustal accretion along slow-spreading ridges in the equatorial Atlantic Ocean

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