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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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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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Imagine a rigid body that is rotating at an angular velocity of ω within an inertial frame of reference. Along with this, picture a second rotating frame that is attached to the body itself. This frame moves along with the body and possesses an angular velocity of Ω. The total moment about the center of mass is calculated by adding the rate of change of angular momentum about the center of mass in relation to the rotating frame and the cross-product of the body's angular velocity...
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Pressure Variation in a Fluid at Rest01:11

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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.
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Differential Form of Maxwell's Equations01:17

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James Clerk Maxwell (1831–1879) was one of the significant contributors to physics in the nineteenth century. He is probably best known for having combined existing knowledge of the laws of electricity and the laws of magnetism with his insights to form a complete overarching electromagnetic theory, represented by Maxwell's equations. The four basic laws of electricity and magnetism were discovered experimentally through the work of physicists such as Oersted, Coulomb, Gauss, and...
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Related Experiment Video

Updated: Oct 3, 2025

Magnetically Induced Rotating Rayleigh-Taylor Instability
06:42

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Axial-Current Anomaly in Euler Fluids.

A G Abanov1, P B Wiegmann2,3

  • 1Department of Physics and Astronomy and Simons Center for Geometry and Physics, Stony Brook University, Stony Brook, New York 11794, USA.

Physical Review Letters
|February 18, 2022
PubMed
Summary
This summary is machine-generated.

A quantum field theory anomaly, the axial-current anomaly, is shown to have a classical analog in Euler fluids. This anomaly breaks the conservation of axial current (fluid helicity) in the presence of electromagnetic fields.

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Area of Science:

  • Fluid dynamics
  • Quantum field theory
  • Electromagnetism

Background:

  • The axial-current anomaly is a key concept in quantum field theories, impacting particle physics.
  • Fluid dynamics describes the motion of fluids, with Euler's equation being a fundamental model for inviscid flow.

Purpose of the Study:

  • To explore the existence of an axial-current anomaly in classical fluid dynamics.
  • To establish a connection between quantum field theory anomalies and classical fluid behavior.

Main Methods:

  • Analysis of the classical Euler fluid equations.
  • Comparison with the mathematical structure of quantum field theory anomalies.
  • Investigating the role of external electromagnetic fields.

Main Results:

  • A close analog of the axial-current anomaly is identified in classical Euler fluids.
  • The conservation of the axial current, related to helicity in inviscid barotropic flow, is shown to be anomalously broken.
  • The anomaly is mathematically expressed as ∂_{μ}j_{A}^{μ}=2E·B, mirroring quantum electrodynamics (QED).

Conclusions:

  • Quantum field theory anomalies can manifest in classical systems like fluids.
  • The Euler fluid provides a classical system to study phenomena analogous to quantum anomalies.
  • This finding bridges concepts from high-energy physics and fluid dynamics.