Ueber das Zeitgesetz des kapillaren Aufstiegs von Flüssigkeiten
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This article is published in Colloid and Polymer Science.The article was published on 1918-07-01 and is currently open access. It has received 1052 citations till now.read more
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Assessing the rapid flow in multilayer paper-based microfluidic devices
TL;DR: In this article, a theoretical assessment of fluid transport in multilayer paper-based microfluidic devices is presented, which predicts the occurrence of fluid velocities 2 orders of magnitude larger than those measured in single-layer paper, and the variation of fluid velocity as a function of the gap thickness, which presents a particular maximum.
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Evaporative Lithography in Open Microfluidic Channel Networks.
TL;DR: A direct capillary-driven method based on wetting and evaporation of various suspensions to fabricate regular two-dimensional wires in an open microfluidic channel through continuous deposition of micro- or nanoparticles under evaporative lithography, akin to the coffee-ring effect is demonstrated.
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A Generalized Capillary Imbibition Model for Porous Media in Tight Reservoirs
TL;DR: Wang et al. as discussed by the authors derived a generalized capillary imbibition model considering the flow resistance and apparent viscosity of fluids in tight porous media, which is more consistent with the experimental results and has a wider applicability.
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Capillary climb dynamics in the limits of prevailing capillary and gravity force.
TL;DR: In this paper, the scaling of the climbing height of a wetting liquid into a porous medium was studied numerically, and the scaling power was expressed as a power law function of time.
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Incorporation of viscosity scaling group into analysis of MPMS index for laboratory characterization of wettability of reservoir rocks
TL;DR: In this paper, the authors proposed a viscosity scaling group (VSG) to relax the need for the limiting condition of the same visco-ity ratio between the native- or restored-state and reference systems in the MPMS method.