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Related Concept Videos

Viscosity of Fluid01:19

Viscosity of Fluid

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.
Accelerating Fluids01:17

Accelerating Fluids

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.
The motion of the liquid within this infinitesimal cylinder is considered to obtain the pressure difference. Three vertical forces act on this liquid:
Capillarity in Fluid01:19

Capillarity in Fluid

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...
Characteristics of Fluids01:20

Characteristics of Fluids

When a force is applied parallel to the top surface of a solid, it resists the applied force due to the internal frictional forces between the layers of the solid known as shearing resistance. However, when the force is removed, the shearing forces restore the original shape of the solid. Other deformation forces also cause temporary changes in shape if the forces are not beyond a threshold magnitude. Solids tend to retain their shape, making the study of their rest and motion easier. Beyond...
Characteristics of Fluids01:31

Characteristics of Fluids

Fluids differ from solids primarily in their molecular structure and stress response. Solids have tightly packed molecules with strong intermolecular forces, maintaining their shape and resisting deformation. In contrast, fluids have molecules spaced farther apart with weaker forces, allowing them to flow and deform easily.
Fluids, which include both liquids and gases, are substances that deform continuously under shearing stress. For example, water and oil are liquids with molecules that can...
Laminar and Turbulent Flow01:07

Laminar and Turbulent Flow

Fluid dynamics is the study of fluids in motion. Velocity vectors are often used to illustrate fluid motion in applications like meteorology. For example, wind—the fluid motion of air in the atmosphere—can be represented by vectors indicating the speed and direction of the wind at any given point on a map. Another method for representing fluid motion is a streamline. A streamline represents the path of a small volume of fluid as it flows. When the flow pattern changes with time, the streamlines...

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Related Experiment Video

Updated: Jun 10, 2026

An Analog Macroscopic Technique for Studying Molecular Hydrodynamic Processes in Dense Gases and Liquids
11:03

An Analog Macroscopic Technique for Studying Molecular Hydrodynamic Processes in Dense Gases and Liquids

Published on: December 4, 2017

da Vinci fluids, catch-up dynamics and dense granular flow.

R Blumenfeld1, S F Edwards, M Schwartz

  • 1Institute of Shock Physics, Imperial College, London, UK. rbb11@cam.ac.uk

The European Physical Journal. E, Soft Matter
|July 30, 2010
PubMed
Summary

We introduce a da Vinci fluid model, dominated by solid friction, exhibiting dense granular fluid behavior like plug flow. Plug regions grow with a characteristic (time)¹(/)³ rate, applicable to granular materials.

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Area of Science:

  • Physics
  • Rheology
  • Materials Science

Background:

  • Dense granular flows exhibit complex rheological behaviors.
  • Understanding friction's role in fluid dynamics is crucial for granular materials.

Purpose of the Study:

  • Introduce and analyze a novel "da Vinci fluid" model.
  • Investigate the emergence and dynamics of plug flow in granular fluids.
  • Determine the growth rate of plug regions.

Main Methods:

  • Analysis of a discrete model for flow rheology.
  • Coarse-graining the discrete model to a continuum description.
  • Mathematical analysis of plug nucleation and expansion.

Main Results:

  • The da Vinci fluid model replicates dense granular fluid behavior, including plug flow.
  • Plug boundaries expand, with a characteristic linear growth rate of (time)¹(/)³ for uniform friction.
  • The model provides insights into plug nucleation and development.

Conclusions:

  • The da Vinci fluid model offers a valuable framework for studying granular materials.
  • Solid friction plays a dominant role in the observed plug flow dynamics.
  • The findings contribute to the understanding of rheology in granular systems.