Dissimilar Electro-Osmotic Flow and Ionic Current Recirculation Patterns in Porous Media Detected by NMR Mapping Experiments
- 2 May 2006
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 96 (17) , 174501
- https://doi.org/10.1103/physrevlett.96.174501
Abstract
Random-site percolation clusters were milled into ceramic (polar) and polystyrene (nonpolar) plates as a paradigm for porous media or complex microsystem channel networks. The pore space was filled with electrolyte solutions. Using NMR microscopy techniques, maps of the following quantities were recorded: (i) flow velocity driven by external pressure gradient, (ii) electro-osmotic flow (EOF) velocity, (iii) ionic current density in the presence of EOF, (iv) ionic current density in the absence of EOF. As far as possible, the experiments were supplemented by computational fluid dynamics simulations. It is shown that electro-osmotic flow as well as the electric current density include vortices and recirculation patterns. Remarkably, all transport patterns turned out to be dissimilar, and the occurrence and positions of vortices do not coincide in the different maps.Keywords
This publication has 19 references indexed in Scilit:
- Electro-osmotic flow of a model electrolytePhysical Review E, 2005
- Observation of electro-osmotic flow echoes in porous media by nuclear magnetic resonancePhysical Review E, 2003
- Low‐voltage electroosmosis pump for stand‐alone microfluidics devicesElectrophoresis, 2003
- Rayleigh-Bénard percolation transition of thermal convection in porous media: Computational fluid dynamics, NMR velocity mapping, NMR temperature mappingPhysical Review E, 2002
- Maps of electric current density and hydrodynamic flow in porous media: NMR experiments and numerical simulationsPhysical Review E, 2002
- Flow through percolation clusters: NMR velocity mapping and numerical simulation studyPhysical Review E, 2001
- Conditions for Similitude between the Fluid Velocity and Electric Field in Electroosmotic FlowAnalytical Chemistry, 2000
- Generation of transverse fluid currents and forces by an electric field: Electro-osmosis on charge-modulated and undulated surfacesPhysical Review E, 1996
- Sensitivity of magnetic-resonance current-density imagingJournal of Magnetic Resonance (1969), 1992
- Mapping of electrical circuits using chemical-shift imagingJournal of Magnetic Resonance (1969), 1988