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Gauss's Law: Cylindrical Symmetry01:20

Gauss's Law: Cylindrical Symmetry

A charge distribution has cylindrical symmetry if the charge density depends only upon the distance from the axis of the cylinder and does not vary along the axis or with the direction about the axis. In other words, if a system varies if it is rotated around the axis or shifted along the axis, it does not have cylindrical symmetry. In real systems, we do not have infinite cylinders; however, if the cylindrical object is considerably longer than the radius from it that we are interested in,...
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In analyzing a thin-walled hollow shaft subjected to torsional loading, a segment with width dx is isolated for examination. Despite its equilibrium state, this segment faces torsional shearing forces at its ends. These forces are quantitatively described by the product of the longitudinal shearing stress on the segment's minor surface and the area of this surface, leading to the concept of shear flow. This shear flow is consistent throughout the structure, indicating a uniform distribution of...
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A spherical capacitor consists of two concentric conducting spherical shells of radii R1 (inner shell) and R2 (outer shell). The shells have equal and opposite charges of +Q and −Q, respectively. For an isolated conducting spherical capacitor, the radius of the outer shell can be considered to be infinite.
Conventionally, considering the symmetry, the electric field between the concentric shells of a spherical capacitor is directed radially outward. The magnitude of the field, calculated by...
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Gauss's Law: Spherical Symmetry01:26

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A charge distribution has spherical symmetry if the density of charge depends only on the distance from a point in space and not on the direction. In other words, if the system is rotated, it doesn't look different. For instance, if a sphere of radius R is uniformly charged with charge density ρ0, then the distribution has spherical symmetry. On the other hand, if a sphere of radius R is charged so that the top half of the sphere has a uniform charge density ρ1 and the bottom half has a uniform...
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The existence of combined electric and magnetic fields that propagate through space as electromagnetic (EM) waves is the most significant prediction of Maxwell's equations. As Maxwell's equations hold in free space, the predicted electromagnetic waves do not require a medium for their propagation. An EM wave comprises an electric field, defined as the force per charge on a stationary charge, and a magnetic field, which is the force per charge on a moving charge.
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Related Experiment Video

Updated: May 20, 2026

Experimental Investigation of Secondary Flow Structures Downstream of a Model Type IV Stent Failure in a 180° Curved Artery Test Section
11:00

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Wave based analysis of the Green's function for a layered cylindrical shell.

Elizabeth A Magliula1, J Gregory McDaniel

  • 1NAVSEA Newport, Newport, Rhode Island 02841-5047, USA. elizabeth.magliula@navy.mil

The Journal of the Acoustical Society of America
|July 12, 2012
PubMed
Summary

This study presents a wave-based method to analyze elastic wave propagation in layered cylindrical shells. The findings aid in designing shells with specific anisotropic properties for advanced applications.

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Area of Science:

  • Mechanical Engineering
  • Materials Science
  • Acoustics

Background:

  • Layered cylindrical shells are crucial in various engineering applications.
  • Understanding elastic wave propagation in these structures is essential for design and performance.
  • Anisotropy in shell layers significantly influences wave behavior.

Purpose of the Study:

  • To develop a wave-based analysis for the Green's function of layered cylindrical shells.
  • To provide a tool for designing shells with controlled elastic wave generation and propagation.
  • To investigate the impact of anisotropic layers on wave dynamics.

Main Methods:

  • Utilized finite element discretizations in the radial coordinate.
  • Employed Fourier series expansions in the circumferential coordinate.
  • Developed a state-space formulation with residue integration for axial domain inversion.

Main Results:

  • Derived an expression for the Green's function as a sum of natural waves.
  • The method accommodates arbitrarily thick shells due to radial discretization.
  • Demonstrated the influence of fiber orientation in anisotropic materials on the Green's function.

Conclusions:

  • The developed wave-based analysis effectively characterizes elastic wave propagation in layered cylindrical shells.
  • The approach allows for detailed study of anisotropic effects on wave behavior.
  • This work provides a valuable tool for the design of advanced composite cylindrical structures.