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Details of Award

NERC Reference : NE/P020909/1

Characterising devolatilisation beneath the Mariana Forearc

Grant Award

Principal Investigator:
Professor DAH Teagle, University of Southampton, Sch of Ocean and Earth Science
Science Area:
Earth
Marine
Overall Classification:
Unknown
ENRIs:
Biodiversity
Environmental Risks and Hazards
Global Change
Natural Resource Management
Science Topics:
Oceanic crust
Ore deposits & mineralisation
Subduction zones
Earth Resources
Ocean drilling
Continental margins
Faulting
Hydrothermal fluids
Mineral deposits
Earthquakes
Faulting
Plate boundary tectonics
Seismicity
Subduction zones
Tectonic systems
Geohazards
Hydrogeology
Permeability
Submarine groundwater
Geochemistry
Mantle composition
Ocean drilling
Plate tectonics
Subduction
Mantle & Core Processes
Faulting
Earthquakes
Tectonic Processes
Mantle processes
Metamorphic petrology
Ocean drilling
Oceanic crust
Plate margins
Plate tectonics
Seismicity
Subduction
Abstract:
There are two types of crust that make up the plates of the World; oceanic and continental, the former is thin and dense and underlies the oceans of the world; and the latter is considerably thicker and more buoyant and makes up the continents. Oceanic crust forms at divergent plate boundaries known as mid ocean ridges, chains of underwater volcanoes. As the newly formed crust ages and moves further from the ridge it cools, becomes denser and sinks. Where a convergent plate boundary occurs between oceanic and continental crust the denser oceanic crust sinks and subducts beneath the continental crust. Where convergence occurs between two oceanic plates, the older, denser plate sinks and subducts. Such boundaries are responsible for the deepest oceanic trenches on Earth, for example the Mariana Trench (deepest point 11,033 m). Subduction zones are the principal areas on Earth where crustal materials are transported into the mantle and therefore represent the fundamental recycling process in plate tectonic theory. Geological processes at these convergent margins control seismicity, plutonism and associated volcanism, and geochemical cycling between the ocean, crust and mantle. These margins commonly generate large, tsunamigenic earthquakes, thus understanding the physical properties controlling seismogenesis at the subduction interface is key to elucidating plate boundary behaviour. Sediments and crustal rocks experience changing pressures and temperatures as they subduct, minerals become unstable and breakdown to form new, denser minerals, and in doing so release fluids that are buoyant and rise into the faults above where earthquakes nucleate and interact with overlying mantle rocks. The chemical and physical changes that the subducting plate undergoes prior to the onset of melting controls earthquake behaviour, geochemical cycling and magmatism at these plate boundaries. To study these processes old pieces of subduction zones that have been uplifted onto the present day continental crust have been studied, but the chemical and physical changes that occurred during the transport of these sections of oceanic crust onto the continents are poorly constrained, and there are large errors on estimated pressures and temperatures of formation. Studying these processes in situ is difficult because they occur deep in the crust and in the some of deepest stretches of water on Earth. Subduction zones that are covered by thick piles of accreted sediments have been successfully drilled, but the thick sediment piles obscures signatures of deep fluids and so the deep subduction zone processes cannot be studied. At the Mariana convergent margin, the Pacific Plate subducts under the Mariana Plate where there is little sediment overburden. The Mariana Plate is faulted and these faults are associated with mud volcanoes. The mud volcanoes originate from the passage of fluids liberated from the subducting plate and carry material from this plate and chemically altered overlying mantle with them. This provides a unique opportunity to sample fluids generated during subduction and materials from the subducting plate without having to drill deep. We will use samples from the IODP Expedition 366 drilling into mud volcanoes in the Mariana forearc to analyse waters generated during subduction. Previous work shows that fluid chemistry changes as the plate moves deeper. We will measure the isotopic ratios of different chemical tracers in the fluids to document the evolution of these processes and metamorphic transformations in the downgoing rocks and the chemical reactions the fluids facilitate in the overlying mantle. This information will be combined with analyses of rocks that are transported with the fluids to quantify what is carried into the deeper subduction zone and what is liberated to the crust and ocean above. These analyses will help to constrain the reactions controlling the strength of materials where earthquakes nucleate.
Period of Award:
8 Dec 2016 - 30 Sep 2018
Value:
£102,100
Authorised funds only
NERC Reference:
NE/P020909/1
Grant Stage:
Completed
Scheme:
Directed (RP) - NR1
Grant Status:
Closed
Programme:
UK IODP Phase2

This grant award has a total value of £102,100  

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FDAB - Financial Details (Award breakdown by headings)

DI - Other CostsIndirect - Indirect CostsDA - InvestigatorsDA - Estate CostsDI - StaffDI - T&SDA - Other Directly Allocated
£5,650£14,495£355£8,356£60,758£3,613£8,873

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