Your search keyword '"*SLABS (Structural geology)"' showing total 3 results

1. Tracing material transport during subduction inception: Insights from potassium isotopes in the crustal sequence of the Troodos ophiolite.

Author

Pan, Qi-Qi, Xiao, Yan, Su, Ben-Xun, Robinson, Paul T., Li, Wen-Jun, Wang, Jing, and Liu, Xia

Subjects

*SUBDUCTION zones, *ISOTOPES, *SUBDUCTION, *ISOTOPIC fractionation, *POTASSIUM, *OCEANIC crust, *URANIUM-lead dating, *COMPLEX variables, *SLABS (Structural geology)

Abstract

Potassium (K) isotopic compositions for a suite of crustal rocks (plutonic unit, sheeted dike complex, and volcanic sequence) in the Troodos ophiolite, Cyprus, were determined to investigate fluid-transport processes during subduction inception. The gabbros and plagiogranites in the plutonic unit have restricted K isotopic compositions (0.01–0.20 ‰ and −0.17 to 0.02 ‰, respectively), whereas diabases in the sheeted dike complex have variable δ41K values from −0.24 to 1.13 ‰. The δ41K values of the volcanic sequence range from −0.26 to −0.07 ‰ in the lower pillow lavas, and from −0.71 to 0.34 ‰ in the upper pillow lavas. These δ41K values are clearly distinct from those of subducting sediments and altered oceanic crust, ruling out direct crustal input as the cause of the unusually heavy K isotopic compositions. Rather, the high K/Th, K/U, and Sr/Th ratios of the investigated samples, together with binary mixing modelling, reveal that the anomalously heavy K isotopic compositions in Troodos rocks are attributed to the influx of fluids during subduction inception. Notably, the δ41K values in the crustal rocks of the Troodos ophiolite are more variable and extend to higher values than those of arc-front and rear-arc lavas of the Izu arc and arc lavas of Martinique in the Lesser Antilles, indicating continuous K isotope fractionation during slab dehydration. Thus, the heavy K isotopic compositions of the Troodos ophiolite reflect K isotope fractionation during dehydration of a shallow slab within a newly formed subduction system, where heavy K isotopes preferentially enter into the aqueous fluids. Later, progressive breakdown of K-bearing phases at deeper levels results in isotopically lighter hydrous melts, which can be delivered to the arc. [ABSTRACT FROM AUTHOR]

Published

2024

2. Seismic evidence for possible entrainment of rising plumes by subducting slab induced flow in three subduction zones surrounding the Caribbean Plate.

Author

Saki, Morvarid, Wirp, Sara Aniko, Billen, Magali, and Thomas, Christine

Subjects

*SLABS (Structural geology), *SUBDUCTION zones, *PLATE tectonics, *TRANSITION flow, *TOMOGRAPHY, *SUBDUCTION

Abstract

The dynamic processes associated with subducting tectonic plates and rising plumes of hot material are typically treated separately in dynamical models and seismological studies. However, various types of observations and related models indicate these processes overlap spatially. Here we use precursors to PP and SS reflecting off mantle transition zone discontinuities to map deflections of these discontinuities near three subduction zones surrounding the Caribbean Plate: 1) Lesser Antilles, 2) Middle America and 3) northern South American subduction zones. In all three regions slow seismic anomalies are present behind the sinking slab within the transition zone in tomographic images. Using array methods, we identify precursors and verify their in-plane propagation for M W ≥ 5.8 events occurring between the years 2000 and 2020 by generating a large number of source receiver combinations with reflection points in the area, including crossing ray paths. The measured time lag between PP/SS arrivals and their corresponding precursors on robust stacks are used to measure the depth of the mantle transition zone discontinuities. In all three areas we find evidence for upward deflection of the 660 discontinuity behind the sinking slab, consistent with the presence of hot plume material (average temperature anomalies of 180 to 620 K), while there is not a corresponding downward deflection of the 410 km discontinuity. One interpretation of these disparate observations is suggested based on comparison to existing models of mantle convection and subduction: plume material rising across 660 km discontinuity could be entrained by lateral flow in the transition zone induced by the nearby sinking slab, and thus delaying the rise of hot material across the 410 km discontinuity. [ABSTRACT FROM AUTHOR]

Published

2024

3. Lesser Antilles slab reconstruction reveals lateral slab transport under the Caribbean since 50 Ma.

Author

Chen, Yi-Wei, Wu, Jonny, and Goes, Saskia

Subjects

*SLABS (Structural geology), *SUBDUCTION, *SUBDUCTION zones, *SURFACE plates, *PLATE tectonics, *EOCENE Epoch

Abstract

• The slab-unfolding links plates and slabs without assumed vertical slab sinking. • The Lesser Antilles slab was laterally transported up to ∼900 km after subduction. • We reconstruct up to 18 mm/yr lateral slab transport since 50 Ma. • A new pre-subduction ridge-transform system of the Proto-Caribbean is presented. The link between surface tectonic plates and mantle slabs is fundamental for paleo-tectonic reconstructions and for our understanding of mantle dynamics. Many seismic tomography-based studies have assumed vertical slab sinking and projected mantle features to the surface to reconstruct paleo-trench locations or explain tectonic features. Here, we used a slab-unfolding approach that does not require assumptions about sinking paths or rates to re-interpret the seismic structure of the Lesser Antilles slab underneath the Caribbean. A recent study invoked mainly vertical slab sinking and a highly folded and deformed slab to explain seismic Caribbean mantle structures. However, our results show that the upper-mantle Lesser Antilles slab structure can be better explained by limited intra-slab deformation and up to ∼900 km lateral slab transport towards the northwest after subduction. Our results indicate that such lateral slab transport can occur even with probable weaknesses in the slab that originate from a subducted fossil ridge-transform system. We ascribe the lateral slab transport in the mantle to a kinematic connection with the North American plate, which has migrated northwestward since the Eocene. [ABSTRACT FROM AUTHOR]

Published

2024