Coupled petrological-geodynamical modeling of a compositionally heterogeneous mantle plume

Self-consistent geodynamic modeling that includes melting is challenging as the chemistry of the source rocks continuously changes as a result of melt extraction. Here, we describe a new method to study the interaction between physical and chemical processes in an uprising heterogeneous mantle plume...

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Bibliographic Details
Published in:Tectonophysics 2018-01, Vol.723, p.242-260
Main Authors: Rummel, Lisa, Kaus, Boris J.P., White, Richard W., Mertz, Dieter F., Yang, Jianfeng, Baumann, Tobias S.
Format: Article
Language:English
Subjects:
Asthenosphere
Chemical composition
Chemical reactions
Chemistry
Coupled numerical models
Decompression
Depletion
Evolution
Geophysics
Geothermal gradient
Lava
Lithosphere
Magma
Magma chemistry
Mantle
Mantle plumes
Mathematical models
Melting
Melts
Methods
Modelling
Organic chemistry
Phase diagrams
Plate tectonics
Plume
Rock
Rocks
Thermodynamic models
Volcanic fields
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Summary:Self-consistent geodynamic modeling that includes melting is challenging as the chemistry of the source rocks continuously changes as a result of melt extraction. Here, we describe a new method to study the interaction between physical and chemical processes in an uprising heterogeneous mantle plume by combining a geodynamic code with a thermodynamic modeling approach for magma generation and evolution. We pre-computed hundreds of phase diagrams, each of them for a different chemical system. After melt is extracted, the phase diagram with the closest bulk rock chemistry to the depleted source rock is updated locally. The petrological evolution of rocks is tracked via evolving chemical compositions of source rocks and extracted melts using twelve oxide compositional parameters. As a result, a wide variety of newly generated magmatic rocks can in principle be produced from mantle rocks with different degrees of depletion. The results show that a variable geothermal gradient, the amount of extracted melt and plume excess temperature affect the magma production and chemistry by influencing decompression melting and the depletion of rocks. Decompression melting is facilitated by a shallower lithosphere-asthenosphere boundary and an increase in the amount of extracted magma is induced by a lower critical melt fraction for melt extraction and/or higher plume temperatures. Increasing critical melt fractions activates the extraction of melts triggered by decompression at a later stage and slows down the depletion process from the metasomatized mantle. Melt compositional trends are used to determine melting related processes by focusing on K2O/Na2O ratio as indicator for the rock type that has been molten. Thus, a step-like-profile in K2O/Na2O might be explained by a transition between melting metasomatized and pyrolitic mantle components reproducible through numerical modeling of a heterogeneous asthenospheric mantle source. A potential application of the developed method is shown for the West Eifel volcanic field. •Combined geodynamic and thermodynamic modeling with evolving rock chemistry•New lithosphere dynamic models of magmatic systems•Simulations applied to understand the evolution of a heterogeneous mantle plume•Influence of different mantle sources on magma chemistry is tested.
ISSN:0040-1951
1879-3266
DOI:10.1016/j.tecto.2017.12.022