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Connecting Hindered Transport in Porous Media across Length Scales: From Single-Pore to Macroscopic

Haichao Wu, Dapeng Wang, Daniel K. Schwartz

2020The Journal of Physical Chemistry Letters25 citationsDOIOpen Access PDF

Abstract

Hindered mass transport is widely observed in various porous media; however, there is no universal model capable of predicting transport in porous media due to the heterogeneity of porous structures and the complexity of the underlying microscopic mechanisms. Here, we used a highly ordered porous medium as a model system to directly explore the effects of geometric parameters (i.e., pore size, pore throat size, and tracer particle size) and microscopic interaction parameters (e.g., controlled by ionic strength) on nanoparticle transport in porous environments using single-particle tracking. We found a linear scaling relation between the macroscopic diffusion coefficient and microscopic diffusion behavior involving a combination of parameters associated with pore-scale features and phenomena, including both geometric effects and particle-wall interactions. The proportionality coefficient relating micro and macro behaviors was complex and related to the connectivity of the matrix and the pore-size variation, which could lead to tortuous diffusion pathways, hindering macroscopic transport.

Topics & Concepts

Porous mediumScalingMaterials sciencePorosityDiffusionParticle sizeParticle (ecology)Macroscopic scaleChemical physicsThermodynamicsPhysicsChemistryGeometryGeologyMathematicsComposite materialOceanographyPhysical chemistryQuantum mechanicsNanopore and Nanochannel Transport StudiesGroundwater flow and contamination studiesEnvironmental remediation with nanomaterials
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