Abstract:Earthquakes near oceanic trenches are important for studying incoming plate bending and updip thrust zone seismogenesis, yet are poorly constrained using seismographs on land. We use an ocean bottom seismograph (OBS) deployment spanning both the incoming Pacific Plate and the forearc to study seismicity near the Mariana Trench. The yearlong deployment in 2012-2013 consisted of 20 broadband OBSs and 5 suspended hydrophones, with an additional 59 short period OBSs and hydrophones recording for 1 month. We locate… Show more
“…For example, previous studies suggested the neutral plane with a global average depth of 30-40 km marks the bottom boundary of the mantle hydration, assuming that pore water cannot penetrate the compressional stress regime (Chapple & Forsyth, 1979). Based on near-field OBS observations, the extensional earthquakes are estimated at the depth of ∼20 km below the Moho in the central Mariana, which is much deeper than previous results (Emry et al, 2014) and consistent with the estimated hydration extent derived from the SV-wave velocities (Eimer et al, 2020).…”
Section: Coherence Between Low-velocity Zone (Hydration Zone) and Ben...supporting
The properties of incoming oceanic plates, such as their geometry and water content closely influence various processes in subduction zones, including the generation of earthquakes and arc magmatism (Grove et al., 2009;Shillington et al., 2015). Water content is especially important because water transported by the incoming plate cools the subduction zone, promotes forearc metamorphism, and facilitates the generation of arc magmatism (Fujie et al., 2016;Hyndman & Peacock, 2003). Since the subducting slab is the primary channel through which water can enter the Earth's interior, estimating hydration of the incoming plate at subduction zones is important for studying these processes (Hirschmann, 2006;Van Keken et al., 2011). Especially at the trench-outer rise bending region on the incoming plate, substantial normal faults can extend into the uppermost mantle, and thus water can penetrate through the bending faults into the mantle, leading to a pervasively serpentinized region (Ranero et al., 2003).Seismic imaging significantly contributes to constraining the hydration of subduction zones, since mineral hydration leads to a reduction in seismic velocity (
“…For example, previous studies suggested the neutral plane with a global average depth of 30-40 km marks the bottom boundary of the mantle hydration, assuming that pore water cannot penetrate the compressional stress regime (Chapple & Forsyth, 1979). Based on near-field OBS observations, the extensional earthquakes are estimated at the depth of ∼20 km below the Moho in the central Mariana, which is much deeper than previous results (Emry et al, 2014) and consistent with the estimated hydration extent derived from the SV-wave velocities (Eimer et al, 2020).…”
Section: Coherence Between Low-velocity Zone (Hydration Zone) and Ben...supporting
The properties of incoming oceanic plates, such as their geometry and water content closely influence various processes in subduction zones, including the generation of earthquakes and arc magmatism (Grove et al., 2009;Shillington et al., 2015). Water content is especially important because water transported by the incoming plate cools the subduction zone, promotes forearc metamorphism, and facilitates the generation of arc magmatism (Fujie et al., 2016;Hyndman & Peacock, 2003). Since the subducting slab is the primary channel through which water can enter the Earth's interior, estimating hydration of the incoming plate at subduction zones is important for studying these processes (Hirschmann, 2006;Van Keken et al., 2011). Especially at the trench-outer rise bending region on the incoming plate, substantial normal faults can extend into the uppermost mantle, and thus water can penetrate through the bending faults into the mantle, leading to a pervasively serpentinized region (Ranero et al., 2003).Seismic imaging significantly contributes to constraining the hydration of subduction zones, since mineral hydration leads to a reduction in seismic velocity (
“…The refraction data sample only a few km beneath the Moho, and cannot provide information on how deep bend-related faulting and hydration extend. However, other observations, including Rayleigh wave dispersion and anisotropy (Cai et al, 2018) and earthquake hypocenters (Eimer et al, 2020;Emry et al, 2014), show that extensional faulting extends to greater depths than sampled in this study.…”
Section: Implications For Subduction Zone Water Fluxcontrasting
Subduction zones are a locus of material transfer between the surface and the solid Earth and play a key role in global cycling of water and other volatiles over geologic time. Balancing the global water budget requires knowing the amount of water recycled to the mantle by subduction, but current estimates span an order of magnitude (Hacker, 2008;Rupke, 2004;Schmidt & Poli, 2003;van Keken et al., 2011). The largest source of uncertainty for subduction zone water fluxes is the amount of water carried in the subducting slab mantle. Hydrous minerals in the slab mantle are the reservoir most likely to carry water past the volcanic arc and into the deep mantle (Hacker, 2008), so this level of uncertainty represents roughly an order of magnitude difference in the rate at which water moves from surface to subsurface reservoirs, which has implications for eustatic sea level change (Parai & Mukhopadhyay, 2012).Oceanic lithosphere approaching deep ocean trenches tends to form faults due to plate bending, and these bend-related faults promote water circulation and hydration of the incoming plate crust and mantle (Faccenda, 2014;Faccenda et al., 2009;Hatakeyama et al., 2017;Korenaga, 2007). Plate bending can reactivate normal faults inherited from mid-ocean ridge tectonism or, if the incoming plate is subducting oblique to existing weak zones, new faults are broken parallel to the trench (Fujie et al., 2018;Zhou et al., 2015). Serpentinized fault zones may be up to several hundred meters wide, with the extent of serpentinization strongly controlled by permeability, which varies with depth (Hatakeyama et al., 2017). Water carried in the subducting slab can take different paths through the subduction zone: hydrous minerals in the crust tend to dehydrate into the mantle wedge (Jarrard, 2003), generating melts that feed arc volcanoes and potentially contributing to intermediate depth earthquakes (Boneh et al., 2019;Faccenda et al., 2012;Jung et al., 2004), while hydrous phases in deeper and colder parts of the slab can remain stable past the volcanic arc and subduct into the deeper mantle.Observational constraints on the amount of water carried by subducting oceanic lithosphere come primarily from geophysical data and rely on relationships between serpentinization, porosity, and geophysical observables
“… 37 , 38 A well-known example of the hydration of the incoming lithosphere comes from the Middle America Trench, where active bending-related faulting across the entire ocean trench slope penetrates at least 20 km into the plate, promoting the deep percolation of water and hydration of the crust and upper mantle. 22 , 39 , 40 The hydration of upper mantle rock has also been documented below the Moho of the subducting slab at the northern central Chile, 41 central Chile, 23 southernmost Mariana, 42 and Mariana 43 trenches, as shown by a notable reduction in compressional mantle velocities, with a penetration depth of 1–2 km, 22 and even 5–7 km, into the mantle. 41 , 44 , 45 Figure 3 Bending-related normal faults and fracture zones in the southern Mariana Trench (A) Topographic map showing abundant bending-related normal faults occurring on the incoming plate of the southern Mariana Trench.…”
Section: Hadal Lithosphere Associated Fluids and Life Activitiesmentioning
confidence: 93%
“…59 The work by Du et al 59 provides direct evidence that the structural deformation of the incoming plate could substantially influence the hydration of upper basaltic crust, which fosters chemical exchange between the upper ocean crust and seawater in a new way. 43 These newly discovered fluid discharge fields are exhibited by small-scale mud volcanoes and pockmarks in association with varied altered mafic rocks that crop out on the trench slope and are mainly composed of iddingsite. 59 Chemically and physically, this phenomenon differs from the serpentine mud volcano formation associated with the shallower Mariana forearc region.…”
Section: Hydration Of Basaltic Lithosphere Supporting Fluid Dischargementioning
The hadal zone, mostly comprising of deep trenches and constituting of the deepest part of the world's oceans, represents the least explored habitat but one of the last frontiers on our planet. The present scientific understanding of the hadal environment is still relatively rudimentary, particularly in comparison with that of shallower marine environments. In the last 30 years, continuous efforts have been launched in deepening our knowledge regarding the ecology of the hadal trench. However, the geological and environmental processes that potentially affect the sedimentary, geochemical and biological processes in hadal trenches have received less attention. Here, we review recent advances in the geology, biology, and environment of hadal trenches and offer a perspective of the hadal science involved therein. For the first time, we release highdefinition images taken by a new full-ocean-depth manned submersible Fendouzhe that reveal novel species with an unexpectedly high density, outcrops of mantle and basaltic rocks, and anthropogenic pollutants at the deepest point of the world's ocean. We advocate that the hydration of the hadal lithosphere is a driving force that influences a variety of sedimentary, geochemical, and biological processes in the hadal trench. Hadal lithosphere might host the Earth's deepest subsurface microbial ecosystem. Future research, combined with technological advances and international cooperation, should focus on establishing the intrinsic linkage of the geology, biology, and environment of the hadal trenches.
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