Pattern formation and coarsening dynamics in three-dimensional convective mixing in porous media

Fu, Xiaojing; Cueto‐Felgueroso, Luis; Juanes, Rubén

doi:10.1098/rsta.2012.0355

Cited by 54 publications

(58 citation statements)

References 41 publications

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“…This decoupled formulation ((1.3) and (1.4)) has been shown to be a good approximation in systems with fast (but not instantaneous) reactions (Sanchez-Vila, Dentz & Donado 2007). It has been adopted by various authors to study reactions driven by fluid mixing, including calcite dissolution in coastal carbonate aquifers (Rezaei et al 2005;Romanov & Dreybrodt 2006;De Simoni et al 2007) and numerical modelling of laboratory experiments of saltwater-freshwater mixing (Guadagnini et al 2009). In our system, the time to reach geochemical equilibrium is estimated to be of the order of tens of hours, which is indeed small compared with the time for flow and transport over the natural length scale in a typical aquifer (see appendix A).…”

Section: Decoupled Formulation For Multispecies Reactive Transportmentioning

confidence: 98%

“…The phenomenon of convective mixing has been studied through nonlinear simulations in two dimensions (e.g. Riaz et al 2006;Hassanzadeh, Pooladi-Darvish & Keith 2007;Hidalgo & Carrera 2009;Neufeld et al 2010;Hidalgo et al 2012;Szulczewski, Hesse & Juanes 2013;Bolster 2014;Slim 2014), three dimensions (Pau et al 2010;Fu, Cueto-Felgueroso & Juanes 2013) and experimental systems reproducing the conditions for a stationary horizontal layer (Kneafsey & Pruess 2010;Neufeld et al 2010;Backhaus, Turitsyn & Ecke 2011;Slim et al 2013) or a migrating buoyant current MacMinn & Juanes 2013). In the case of three-dimensional simulations, a striking self-organized network pattern is observed near the top boundary layer (Fu et al 2013).…”

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confidence: 96%

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Rock dissolution patterns and geochemical shutdown of –brine–carbonate reactions during convective mixing in porous media

Cueto‐Felgueroso

Bolster

et al. 2015

J. Fluid Mech.

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Motivated by the process of CO 2 convective mixing in porous media, here we study the formation of rock-dissolution patterns that arise from geochemical reactions during Rayleigh-Bénard-Darcy convection. Under the assumption of instantaneous chemical equilibrium, we adopt a formulation of the local reaction rate as a function of scalar dissipation rate, a measure that depends solely on flow and transport, and chemical speciation, which is a measure that depends only on the equilibrium thermodynamics of the chemical system. We use high-resolution simulations to examine the interplay between the density-driven hydrodynamic instability and the rock dissolution reactions, and analyse the impact of geochemical reactions on the macroscopic mass exchange rate. We find that dissolution of carbonate rock initiates in regions of locally high mixing, but that the geochemical reaction shuts down significantly earlier than shutdown of convective mixing. This early shutdown feature reflects the important role that chemical speciation plays in this hydrodynamics-reaction coupled process. Finally, we extend our analysis to three dimensions and explore the morphology of dissolution patterns in three dimensions.

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Section: Decoupled Formulation For Multispecies Reactive Transportmentioning

confidence: 98%

mentioning

confidence: 96%

Rock dissolution patterns and geochemical shutdown of –brine–carbonate reactions during convective mixing in porous media

Cueto‐Felgueroso

Bolster

et al. 2015

J. Fluid Mech.

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“…Alternatively, the approaches of Murray & Ashton [21] to coastline migration, or Da Lio et al [16] to wetland development use nonlinear feedback to make explicit testable predictions, which will be important in attempts to minimize disruption of coastal regions by changing climates. Finally, large-scale experiments on carbon capture and storage will require understanding and engineering patterns of reactive porous media flow over many cubic kilometres and inspired modelling such as that of Fu et al [23].…”

Section: Resultsmentioning

confidence: 99%

“…Similar networks can also be found in surprising places, for example in fluid mixing. Fu et al [23] present a numerical study of the dissolution of CO 2 that is expected as a result of carbon capture and storage in underground aquifers. The convective mixing initially selects a most unstable wavelength, but the pattern rapidly develops into a well-defined cellular network of columnar fingers of CO 2 -rich fluid.…”

Section: Contents Of This Issuementioning

confidence: 99%

Pattern formation in the geosciences

Goehring

2013

Phil. Trans. R. Soc. A.

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Pattern formation is a natural property of nonlinear and non-equilibrium dynamical systems. Geophysical examples of such systems span practically all observable length scales, from rhythmic banding of chemical species within a single mineral crystal, to the morphology of cusps and spits along hundreds of kilometres of coastlines. This article briefly introduces the general principles of pattern formation and argues how they can be applied to open problems in the Earth sciences. Particular examples are then discussed, which summarize the contents of the rest of this Theme Issue.

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“…Although an extra freedom in 3D may lead to more complicated convective patterns and affect the transport efficiency, the studies by [38,53,54] show that in 3D the flow still retains a similar columnar structure at large Ra in horizontal porous layers, and the convective flux increases linearly with Ra but with a slightly larger prefactor. Therefore, the analysis in 2D does, indeed, shed light on the real 3D system.…”

Section: Vs 3dmentioning

confidence: 99%

A short review on porous media convection

shao¹

2018

Preprint

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We briefly review the investigations of pattern formation and transport properties of RayleighDarcy convection (or the Elder Problem), including laboratory experiments, theoretical analysis and numerical simulations. It is shown that the flow exhibits power-law-scaling characteristics at large Rayleigh-Darcy number Ra, a dimensionless parameter representing the ratio of the driving buoyancy forces to the diffusive forces. Namely, the mean spacing between neighboring interior plumes shrinks as Ra −α with the scaling exponent α ≤ 1/2 and the convective flux increases linearly with Ra. However, more laboratory experiments are needed to validate these scalings. Additionally, many conditions, e.g. the inclination of the layer and hydrodynamic dispersion, etc., may lead to a large uncertainty in the flow pattern and transport efficiency.

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Pattern formation and coarsening dynamics in three-dimensional convective mixing in porous media

Cited by 54 publications

References 41 publications

Rock dissolution patterns and geochemical shutdown of –brine–carbonate reactions during convective mixing in porous media

Rock dissolution patterns and geochemical shutdown of –brine–carbonate reactions during convective mixing in porous media

Pattern formation in the geosciences

A short review on porous media convection

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