Numerical modelling of multiphase multicomponent reactive transport in the Earth’s interior

Oliveira, Beñat; Afonso, Juan Carlos; Zlotnik, Sergio; Dı́ez, Pedro

doi:10.1093/gji/ggx399

Cited by 21 publications

(29 citation statements)

References 121 publications

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“…Our compaction model thus extends previous theories by including other processes than divergent flow (e.g., McKenzie, 1984;Bercovici & Ricard, 2003;Oliveira et al, 2018) and reactive volume change (e.g., Šrámek et al, 2007).…”

Section: Mechanical Equationssupporting

confidence: 73%

“…Depending on the mechanical and thermal structure of the crust, its thickness (Hildreth & Moorbath, 1988), and regional tectonic regime (Cembrano & Lara, 2009), transport towards the shallow crust is thought to be accommodated by diapirs rising through ductile crust (Bateman, 1984;Cruden, 1990) or by fractures propagating through brittle rock (Clemens & Mawer, 1992;Rubin, 1993;Havlin et al, 2013). Porous melt transport models have been extended to include visco-elastic/brittle-plastic rheologies (Connolly & Podladchikov, 2007;Rozhko et al, 2007;Keller et al, 2013;Yarushina & Podladchikov, 2015;Oliveira et al, 2018), though their application has remained limited.…”

Section: Multi-phase Reactive Transports In Igneous Systemsmentioning

confidence: 99%

“…This choice implies that there is no resistance to purely rotational motion, and that angular momentum is conserved, since q i v = q i v T now holds. In (25), we have made a distinction between mechanical and thermodynamic pressures, where the former is a third of the trace of (25), and the latter accounts for irreversible deformation internal to compressible phases, (Bennethum & Weinstein, 2004;Moulas et al, 2019;Oliveira et al, 2018). To reduce complexity, as well as to emphasise the multi-phase nature of compaction, we choose to set the volumetric coefficient to zero, Λ i V = 0, and hence maintain a single pressure definition, P i = P i , in (23c).…”

Section: Fluxesmentioning

confidence: 99%

“…The reason is that we assume their systemscale volumetric deformation to be dominated by phase compaction, not phase compressibility (i.e., ∂φ i /∂t ρ i −1 ∂ρ i /∂t). The two-phase compaction model of McKenzie (1984), and the recent extension to n phases by Oliveira et al (2018) both use the volumetric term in the stress tensor to formulate phase compaction. Hence, they do not distinguish formally between system-scale volumetric flow resulting from irreversible bulk deformation internal to compressible phases, and local-scale solenoidal flow of phases accommodating changes in phase fractions.…”

Section: Fluxesmentioning

confidence: 99%

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A continuum model of multi-phase reactive transport in igneous systems

Keller

Suckale

2019

Geophysical Journal International

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Multi-phase reactive transport processes are ubiquitous in igneous systems. A challenging aspect of modelling igneous phenomena is that they range from solid-dominated porous to liquiddominated suspension flows and therefore entail a wide spectrum of rheological conditions, flow speeds, and length scales. Most previous models have been restricted to the two-phase limits of porous melt transport in deforming, partially molten rock and crystal settling in convecting magma bodies. The goal of this paper is to develop a framework that can capture igneous system from source to surface at all phase proportions including not only rock and melt but also an exsolved volatile phase. Here, we derive an n-phase reactive transport model building on the concepts of Mixture Theory, along with principles of Rational Thermodynamics and procedures of Non-equilibrium Thermodynamics. Our model operates at the macroscopic system scale and requires constitutive relations for fluxes within and transfers between phases, which are the processes that together give rise to reactive transport phenomena. We introduce a phase-and process-wise symmetrical formulation for fluxes and transfers of entropy, mass, momentum, and volume, and propose phenomenological coefficient closures that determine how fluxes and transfers respond to mechanical and thermodynamic forces. Finally, we demonstrate that the known limits of two-phase porous and suspension flow emerge as special cases of our general model and discuss some ramifications for modelling pertinent two-and three-phase flow problems in igneous systems.

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Section: Mechanical Equationssupporting

confidence: 73%

Section: Multi-phase Reactive Transports In Igneous Systemsmentioning

confidence: 99%

Section: Fluxesmentioning

confidence: 99%

Section: Fluxesmentioning

confidence: 99%

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A continuum model of multi-phase reactive transport in igneous systems

Keller

Suckale

2019

Geophysical Journal International

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“…A petrological tool based on melting parameterization has been developed recently (Brown and Lesher, 2016), and in principle it could be used in combination with some dynamic model as well. Numerous studies investigated the dynamic evolution of melt and solid mantle using a twophase flow model (McKenzie, 1984;Stevenson, 1984, 1986;Spiegelman, 1993;Richardson, 1998;Ghods and Arkani-Hamed, 2000;Schmeling, 2000;Bercovici et al, 2001;Bercovici and Ricard, 2003;Spiegelman et al, 2007;Hewitt and Fowler, 2008;Katz, 2008;Hewitt, 2010;Rudge et al, 2011;Oliveira et al, 2018). The most recent one (Oliveira et al, 2018) incorporates a complex rheology and a realistic thermodynamic equilibrium model.…”

Section: Introductionmentioning

confidence: 99%

Petrological Geodynamics of Mantle Melting II. AlphaMELTS + Multiphase Flow: Dynamic Fractional Melting

Tirone

2018

Front. Earth Sci.

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In this second installment of a series that aims to investigate the dynamic interaction between the composition and abundance of the solid mantle and its melt products, the classic interpretation of fractional melting is extended to account for the dynamic nature of the process. A multiphase numerical flow model is coupled with the program AlphaMELTS, which provides at the moment possibly the most accurate petrological description of melting based on thermodynamic principles. The conceptual idea of this study is based on a description of the melting process taking place along a 1-D vertical ideal column where chemical equilibrium is assumed to apply in two local subsystems separately on some spatial and temporal scale. The solid mantle belongs to a local subsystem (ss1) that does not interact chemically with the melt reservoir which forms a second subsystem (ss2). The local melt products are transferred in the melt subsystem ss2 where the melt phase eventually can also crystallize into a different solid assemblage and will evolve dynamically. The main difference with the usual interpretation of fractional melting is that melt is not arbitrarily and instantaneously extracted from the mantle, but instead remains a dynamic component of the model, hence the process is named dynamic fractional melting (DFM). Some of the conditions that may affect the DFM model are investigated in this study, in particular the effect of temperature, mantle velocity at the boundary of the mantle column. A comparison is made with the dynamic equilibrium melting (DEM) model discussed in the first installment. The implications of assuming passive flow or active flow are also considered to some extent. Complete data files of most of the DFM simulations, four animations and two new DEM simulations (passive/active flow) are available following the instructions in the Supplementary Material.

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Plate Tectonics and Polar Sea Ice

2022

Engineering Physics of High‐Temperature Materials

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Numerical modelling of multiphase multicomponent reactive transport in the Earth’s interior

Cited by 21 publications

References 121 publications

A continuum model of multi-phase reactive transport in igneous systems

A continuum model of multi-phase reactive transport in igneous systems

Petrological Geodynamics of Mantle Melting II. AlphaMELTS + Multiphase Flow: Dynamic Fractional Melting

Plate Tectonics and Polar Sea Ice

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