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Viscosity of Fluid01:19

Viscosity of Fluid

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Viscosity measures the resistance a fluid offers to flow and deformation. It results from internal friction between layers of fluid moving relative to one another. Dynamic viscosity, denoted by the Greek letter mu (μ), quantifies the force needed to move one fluid layer over another. For Newtonian fluids like water and air, the relationship between the shearing stress and the rate of shearing strain is linear, meaning their viscosity remains constant regardless of the applied stress.
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Newtonian Fluid: Problem Solving01:18

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Newtonian fluids exhibit a constant viscosity, meaning their shear stress and shear strain rate are directly proportional. This property ensures a predictable and stable response to applied forces, maintaining a linear relationship between force and flow. Examples include water, air, and light oils, consistently demonstrating this proportional behavior regardless of external conditions.
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Euler's Equations of Motion01:28

Euler's Equations of Motion

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In fluid mechanics, shear stresses arise from viscosity, which represents a fluid's internal resistance to deformation. For low-viscosity fluids, like water, these stresses are minimal, simplifying flow analysis by allowing the fluid to be treated as inviscid, or frictionless. In an inviscid fluid, shear stresses are absent, leaving only normal stresses, which act perpendicularly to fluid elements. Notably, pressure — defined as the negative of the normal stress — remains...
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When a fluid is in constant acceleration, the pressure and buoyant force equations are modified. Suppose a beaker is placed in an elevator accelerating upward with a constant acceleration, a. In the beaker, assume there is a thin cylinder of height h with an infinitesimal cross-sectional area, ΔS.
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Surface Tension of Fluid01:22

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Surface tension is a fundamental property of fluids, occurring at the boundary between a liquid and a gas or between two immiscible liquids. This phenomenon arises from the cohesive forces between molecules at the fluid's surface, creating an effect similar to a stretched elastic membrane. Inside each fluid, molecules are equally attracted in all directions by neighboring molecules, but surface molecules experience a net inward force, resulting in surface tension.
Surface tension varies...
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Fluid Pressure over Curved Plate of Constant Width01:12

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When a curved plate of constant width is submerged in a liquid, the pressure acting normal to the plate varies continuously both in magnitude and direction. Calculating the magnitude and location of the resultant force at a point is often challenging for such cases. One of the methods to determine the resultant force and its location involves separately calculating the horizontal and vertical components of the resultant force. This complex calculation can be simplified by representing the...
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Related Experiment Video

Updated: Jul 18, 2025

Experimental Measurement of Settling Velocity of Spherical Particles in Unconfined and Confined Surfactant-based Shear Thinning Viscoelastic Fluids
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Experimental Measurement of Settling Velocity of Spherical Particles in Unconfined and Confined Surfactant-based Shear Thinning Viscoelastic Fluids

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Single-Bubble Rising in Shear-Thinning and Elastoviscoplastic Fluids Using a Geometric Volume of Fluid Algorithm.

Ahmad Fakhari1, Célio Fernandes2,3

  • 1Department of Biophysics, University of Texas Southwestern Medical Center, 6001 Forest Park Rd, Dallas, TX 75390, USA.

Polymers
|August 26, 2023
PubMed
Summary
This summary is machine-generated.

This study introduces a new computational method for simulating air bubbles in complex fluids. The algorithm accurately models bubble behavior in Newtonian, viscoelastic, and elastoviscoplastic fluids, enabling diverse industrial applications.

Keywords:
OpenFOAMelastoviscoplastic fluidgeometric interface capturing approachmultiphase viscoelastic flows

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Studying Large Amplitude Oscillatory Shear Response of Soft Materials
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Area of Science:

  • Multiphase flow dynamics
  • Computational fluid dynamics
  • Non-Newtonian fluid mechanics

Background:

  • Air bubble motion is critical for heat transfer and material quality.
  • Non-Newtonian fluid properties, like viscosity, are significantly affected by air bubbles.
  • Accurate simulation of bubble dynamics in complex fluids is challenging.

Purpose of the Study:

  • To develop and validate a novel interface-capturing method for multiphase viscoelastic fluid flow.
  • To accurately simulate the buoyancy-driven rise of air bubbles in fluids with varying rheological complexities.
  • To provide a robust computational tool for applications involving bubble dynamics in complex fluids.

Main Methods:

  • Developed a geometric volume of fluid (isoAdvector) approach.
  • Utilized a reconstructed distance function (RDF) for interface curvature.
  • Employed a piecewise linear interface construction (PLIC) scheme for enhanced accuracy.
  • Validated the multiphase viscoelastic PLIC-RDF isoAdvector (MVP-RIA) algorithm with simulations in Newtonian, viscoelastic, and elastoviscoplastic fluids.

Main Results:

  • The MVP-RIA algorithm accurately predicted bubble shape and velocity in Newtonian fluids, matching experimental data.
  • Simulations in viscoelastic fluids revealed bubble shape transitions to prolate/teardrop forms due to normal stress effects.
  • In elastoviscoplastic fluids, bubble deformation was limited for small bubbles, evolving to elongated shapes with multiple tails for larger volumes.
  • Achieved accurate results on coarser grids compared to traditional algebraic Volume of Fluid (VOF) methods.

Conclusions:

  • The developed MVP-RIA algorithm offers a robust and accurate method for simulating multiphase viscoelastic fluid flow.
  • The study demonstrates the algorithm's capability to capture complex bubble deformation and shape transitions in various non-Newtonian fluids.
  • This advancement paves the way for improved simulations in industrial applications like bubble columns, polymer processing, and 3D printing.