Enhanced Mixing and Reaction in Converging Flows: Theory and Pore‐Scale Imaging

Izumoto, Satoshi; Heyman, Joris; Huisman, Johan Alexander; Vriendt, Kevin de; Soulaine, Cyprien; Gomez, Francesco; Tabuteau, Hervé; Méheust, Yves; Borgne, Tanguy Le

doi:10.1029/2023wr034749

Cited by 3 publications

(2 citation statements)

References 68 publications

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“…Close to the lamella, the velocity field that leads to a steady elongation and compression is expressed as v ζ = γζ ; v η = − γη . Therefore, by neglecting the gradients on the elongation direction ζ (much smaller than in the compression direction η), the transport is represented by the Lagrangian compression-diffusion-reaction equation: ∂ a ∂ t = D ∂ 2 a ∂ η 2 + γ η ∂ a ∂ η − k r a b The scaling laws resulting from this model for reactive mixing in a steady front are summarized in Table . The mean stretching rate can be expressed as a nondimensional Lyapunov exponent as λ = γ d v z …”

Section: Resultsmentioning

confidence: 99%

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Microscale Chaotic Mixing as a Driver for Chemical Reactions in Porous Media

Sanquer,

Heyman,

Hanna

et al. 2024

Environ. Sci. Technol.

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Mixing-induced reactions play a key role in a large range of biogeochemical and contaminant transport processes in the subsurface. Fluid flow through porous media was recently shown to exhibit chaotic mixing dynamics at the pore scale, enhancing microscale concentration gradients and controlling mixing rates. While this phenomenon is likely ubiquitous in environmental systems, it is not known how it affects chemical reactions. Here, we use refractive index matching and laser-induced fluorescence imaging of a bimolecular redox reaction to investigate the consequence of pore scale chaotic mixing on the reaction rates. The overestimation of measured reaction rates by the classical macrodispersion model highlights the persistence of incomplete mixing on the pore scale. We show that the reaction product formation is controlled by microscale chaotic mixing, which induces an exponential increase of the mixing interface and of the reaction rates. We derive a reactive transport model that captures experimental results and predicts that chaotic mixing has a first order control on reaction rates across a large range of time scales and Pećlet and Damkoḧler numbers. These findings provide a new framework for understanding, assessing, and predicting mixinginduced reactions and their role on the fate and mobility of environmental compounds in natural porous media.

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Section: Resultsmentioning

confidence: 99%

“…The scaling laws resulting from this model for reactive mixing in a steady front 47 are summarized in Table 3. The mean stretching rate can be expressed as a nondimensional Lyapunov exponent as , where ϕl is the initial front length.…”

Section: Effect Of Chaoticmentioning

confidence: 99%

Microscale Chaotic Mixing as a Driver for Chemical Reactions in Porous Media

Sanquer,

Heyman,

Hanna

et al. 2024

Environ. Sci. Technol.

Self Cite

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Resolving pore-scale concentration gradients for transverse mixing and reaction in porous media

Shafabakhsh,

Le Borgne,

Renard

et al. 2024

Advances in Water Resources

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Oscillating reaction in porous media under saddle flow

Izumoto

2023

Physics of Fluids

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Pattern formation due to oscillating reactions represents variable natural and engineering systems, but previous studies employed only simple flow conditions such as uniform flow and Poiseuille flow. We studied the oscillating reaction in porous media, where dispersion enhanced the spreading of diffusing components by merging and splitting flow channels. We considered the saddle flow, where the stretching rate is constant everywhere. We generated patterns with the Brusselator system and classified them by instability conditions and Péclet number (Pe), which was defined by the stretching rate. The results showed that each pattern formation was controlled by the stagnation point and stable and unstable manifolds of the flow field due to the heterogeneous flow fields and the resulting heterogeneous dispersion fields. The characteristics of the patterns, such as the position of stationary waves parallel to the unstable manifold and the size of local stationary patterns around the stagnation point, were also controlled by Pe.

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Enhanced Mixing and Reaction in Converging Flows: Theory and Pore‐Scale Imaging

Cited by 3 publications

References 68 publications

Microscale Chaotic Mixing as a Driver for Chemical Reactions in Porous Media

Microscale Chaotic Mixing as a Driver for Chemical Reactions in Porous Media

Resolving pore-scale concentration gradients for transverse mixing and reaction in porous media

Oscillating reaction in porous media under saddle flow

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