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Buoyancy and Stability for Submerged and Floating Bodies01:11

Buoyancy and Stability for Submerged and Floating Bodies

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In fluid mechanics, buoyancy and stability are key concepts for understanding the behavior of submerged and floating bodies. When a stationary body is fully or partially submerged in a fluid, the fluid exerts a force on the body known as the buoyant force. This force acts vertically upward through a point called the center of buoyancy, which is the center of the displaced fluid volume. According to Archimedes' principle, the magnitude of the buoyant force is equal to the weight of the fluid...
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Hydraulic Jump01:29

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A hydraulic jump is a sudden rise in fluid depth in open channels, occurring when high-velocity (supercritical) flow transitions to low-velocity (subcritical) flow. This phenomenon requires an upstream Froude number greater than 1, as flows with Fr1<1 remain subcritical, making a hydraulic jump impossible due to the need for negative head loss, which violates thermodynamic principles.The characteristics of a hydraulic jump depend on the upstream Froude number and are classified as...
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Turbulent Flow01:24

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Turbulent flow is characterized by unpredictable fluctuations in velocity and pressure, which result in a chaotic fluid movement distinct from the orderly patterns of laminar flow. While laminar flow is governed by smooth, parallel layers with minimal mixing, turbulent flow exhibits highly irregular, three-dimensional patterns. This behavior arises due to instabilities in the fluid's velocity profile, and amplifies as the flow velocity increases. Minor disturbances, known as turbulent...
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Introduction to Types of Flows01:23

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Fluid flows are categorized by dimensionality and behavior, with one-dimensional flow being the simplest form, where properties like velocity and pressure change only along a single axis. Water moving through straight pipes exemplifies this flow type, as variations in other directions are minimal. One-dimensional analysis helps simplify understanding such flows, focusing solely on changes along the pipe's length.
Two-dimensional flow involves changes in both length and height, as seen in...
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Irrotational Flow01:28

Irrotational Flow

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Irrotational flow is characterized by fluid motion where particles do not rotate around their axes, resulting in zero vorticity. For a flow to be irrotational, the curl of the velocity field must be zero. This imposes specific conditions on velocity gradients. For instance, to maintain zero rotation about the z-axis, the gradient condition:
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General Characteristics of Pipe Flow II01:24

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When fluid enters a pipe, it first passes through the entrance region, where the velocity profile adjusts due to viscous effects. In this region, a boundary layer forms along the pipe walls and grows until it fully occupies the pipe's cross-section. Once the boundary layer merges, the flow becomes fully developed, with a steady velocity profile that remains consistent along the pipe's length.
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Related Experiment Video

Updated: May 6, 2026

Magnetically Induced Rotating Rayleigh-Taylor Instability
06:42

Magnetically Induced Rotating Rayleigh-Taylor Instability

Published on: March 3, 2017

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Some peculiar features of hydrodynamic instability development.

E Meshkov1

  • 1Hydrodynamic Laboratory, Sarov Physical and Technical Institute, , Dukhova Street 6, Sarov, Nizhny Novgorod Region 607186, Russian Federation.

Philosophical Transactions. Series A, Mathematical, Physical, and Engineering Sciences
|October 23, 2013
PubMed
Summary

A density jump at the interface is crucial for turbulent mixing zone (TMZ) development in both gas-liquid and gas-gas systems. This finding is essential for understanding instability evolution under various conditions.

Keywords:
Rayleigh–Taylor instabilityTaylor bubblelaser sheetshock tubeturbulent mixing

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Visually Based Characterization of the Incipient Particle Motion in Regular Substrates: From Laminar to Turbulent Conditions
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Area of Science:

  • Fluid dynamics
  • Plasma physics
  • Astrophysics

Background:

  • Turbulent mixing zones (TMZs) are fundamental in various physical phenomena.
  • Understanding interface instability is key to modeling complex fluid behaviors.

Purpose of the Study:

  • To investigate the structural features of turbulent mixing zones.
  • To identify critical conditions for the continuous development of interface instabilities.

Main Methods:

  • Experimental analysis of Rayleigh-Taylor instability at gas-liquid interfaces.
  • Experimental analysis of Richtmyer-Meshkov instability at gas-gas interfaces accelerated by shock waves.

Main Results:

  • A density jump at the interface is a generic and necessary feature for developed TMZs.
  • The stability of gas bubble cupolas influences the density jump in gas-liquid interfaces.
  • Interface instability can be suppressed by decaying waves moving from light to heavy gas.

Conclusions:

  • The density jump is a universal characteristic of developing TMZs.
  • The direction of wave propagation significantly impacts interface instability.
  • Findings are relevant for astrophysical phenomena and inertial confinement fusion.