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Capillarity in Fluid01:19

Capillarity in Fluid

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Capillarity describes the movement of liquid in small spaces without external forces acting on it. The capillarity is driven by surface tension and adhesive interactions between the liquid and surrounding solid surfaces. This effect is often seen in narrow tubes, porous materials, and fine particles.
Surface tension is crucial to capillarity. It results from cohesive forces between liquid molecules at the liquid-air boundary, forming a skin that resists external forces. When the capillary tube...
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Design Example: Flow of Oil Through Circular Pipes01:25

Design Example: Flow of Oil Through Circular Pipes

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Understanding fluid flow behavior through pipes is critical in fluid mechanics, especially in applications like oil transportation through pipelines. Hagen-Poiseuille's law provides an exact solution derived from the Navier-Stokes equations for steady, incompressible, and laminar flow within a circular pipe. Hagen-Poiseuille's law helps determine the necessary pressure drop across a pipeline section by determining parameters like pipe length, radius, oil viscosity, and the desired...
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Plane Potential Flows01:23

Plane Potential Flows

480
Plane potential flows simplify fluid motion by assuming the fluid to be irrotational and incompressible. These characteristics allow these flows to be described by a velocity potential function, ϕ, representing the flow speed in a given direction, and a stream function, ψ, that visualizes the flow path, both governed by Laplace's equation. These parameters help in estimating flow patterns, velocity distributions, and pressure fields around various hydraulic structures.
Uniform...
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Pressure of Fluids01:14

Pressure of Fluids

17.2K
There are many examples of pressure in fluids in everyday life, such as in relation to blood (high or low blood pressure) and in relation to weather (high- and low-pressure weather systems). A given force can have a significantly different effect, depending on the area over which the force is exerted. For instance, a force applied to an area of 1 mm2 has a pressure that is 100 times greater than the same force applied to an area of 1 cm2. That's why a sharp needle is able to poke through...
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Pressure Variation in a Fluid at Rest01:11

Pressure Variation in a Fluid at Rest

430
In a fluid at rest, the pressure at any point beneath the fluid surface depends solely on the depth, not on the container's shape or size. This principle, known as hydrostatic pressure, arises because, in stationary fluids, there is no acceleration, meaning the forces within the fluid balance out. Only vertical forces, caused by the weight of the fluid above, contribute to pressure changes with depth.
When measuring pressure at two different levels within the fluid, the difference in...
430
Rapidly Varying Flow01:24

Rapidly Varying Flow

158
Rapidly varying flow (RVF) in open channels is characterized by abrupt changes in flow depth over a short distance, with the rate of depth change relative to distance often approaching unity. These flows are inherently complex due to their transient and multi-dimensional nature, making exact analysis difficult. However, approximate solutions using simplified models provide valuable insights into their behavior.Key Features of Rapidly Varying FlowRVF is commonly observed in scenarios involving...
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Related Experiment Video

Updated: Oct 2, 2025

Microfluidic Devices for Characterizing Pore-scale Event Processes in Porous Media for Oil Recovery Applications
08:38

Microfluidic Devices for Characterizing Pore-scale Event Processes in Porous Media for Oil Recovery Applications

Published on: January 16, 2018

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Visualization of Interstitial Pore Fluid Flow.

Linzhu Li1, Magued Iskander1

  • 1Civil and Urban Engineering Department, Tandon School of Engineering, New York University, 6 Metrotech Center, Brooklyn, NY 11201, USA.

Journal of Imaging
|February 24, 2022
PubMed
Summary
This summary is machine-generated.

This study visualizes microscale fluid flow in porous media using a novel transparent model. Results show particle roundness significantly influences turbulence in interstitial flow, aiding internal erosion understanding.

Keywords:
granulometryinter-particlemicroscaleroundnessshape

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Visualizing Cytoplasmic Flow During Single-cell Wound Healing in Stentor coeruleus
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Last Updated: Oct 2, 2025

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Reservoir Condition Pore-scale Imaging of Multiple Fluid Phases Using X-ray Microtomography
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Visualizing Cytoplasmic Flow During Single-cell Wound Healing in Stentor coeruleus
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Visualizing Cytoplasmic Flow During Single-cell Wound Healing in Stentor coeruleus

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Area of Science:

  • Geotechnical Engineering
  • Fluid Dynamics
  • Materials Science

Background:

  • Understanding pore-scale flow is crucial for applications like internal erosion and piping.
  • Previous research often infers microscale phenomena from macroscopic observations.
  • A gap exists in direct visualization of interstitial fluid flow at the microscale.

Purpose of the Study:

  • To introduce an innovative method for visualizing microscale fluid flow through porous media.
  • To compare interstitial flow through different particle shapes (Ottawa sand vs. cylinders).
  • To investigate the relationship between particle morphology and flow characteristics.

Main Methods:

  • Developed a transparent synthetic granular medium using hydrogel particles in 3D-printed molds.
  • Utilized custom 3D-printed jigs for precise particle arrangement.
  • Employed silver-coated hollow microspheres as tracers in the pore fluid.
  • Captured high-speed images and applied particle image velocimetry (PIV) for flow analysis.

Main Results:

  • Successfully visualized interstitial fluid flow at the microscale.
  • Obtained velocity and direction data of fluid movement within the pore space.
  • Demonstrated that particle roundness is directly related to the magnitude of turbulence.
  • Compared flow through Ottawa-shaped particles with flow through perfect cylinders.

Conclusions:

  • The developed method enables direct microscale visualization of pore-scale fluid flow.
  • Particle roundness is a key factor influencing turbulence in porous media flow.
  • Findings contribute to a better understanding of internal erosion mechanisms.