Pore-scale DNS shows intermittency as a network-coupled process of drainage-imbibition cycles that enhances overall fluid mobility and produces the sub-linear macroscopic scaling regime.
From interface dynamics to Darcy scale description of multiphase flow in porous media,
2 Pith papers cite this work. Polarity classification is still indexing.
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Digital Rock Physics is proposed as enabling infrastructure for critical minerals strategies through 3D imaging, AI analysis, modeling, and new data standards to improve viability assessment and circularity.
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Intermittent two-phase flow in porous media: insights from pore-scale direct numerical simulation
Pore-scale DNS shows intermittency as a network-coupled process of drainage-imbibition cycles that enhances overall fluid mobility and produces the sub-linear macroscopic scaling regime.
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Beyond Critical Minerals Targets: Digital Rock Physics as Infrastructure for Secure and Circular Supply Chains
Digital Rock Physics is proposed as enabling infrastructure for critical minerals strategies through 3D imaging, AI analysis, modeling, and new data standards to improve viability assessment and circularity.