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Elastic Strain Energy for Shearing Stresses01:20

Elastic Strain Energy for Shearing Stresses

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As discussed in previous lessons, strain energy in a material is the energy stored when it is elastically deformed, a concept crucial in materials science and mechanical engineering. This energy results from the internal work done against the cohesive forces within the material. When a material undergoes shearing stress and corresponding shearing strain, the strain energy density, which is the energy stored per unit volume, is calculated. Within the elastic limit, where the stress is...
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Plastic Behavior01:21

Plastic Behavior

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A material's elastic behavior is characterized by the disappearance of stress once the load is removed, allowing the material to return to its original state. However, when stress surpasses the yield point, yielding commences, marking the onset of plastic deformation or permanent set. This change from elastic to plastic behavior is influenced by the peak stress value and the duration before the load is removed. An intriguing observation occurs when a specimen is loaded, unloaded, and...
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Relation between Poisson's ratio, Modulus of Elasticity and Modulus of Rigidity01:15

Relation between Poisson's ratio, Modulus of Elasticity and Modulus of Rigidity

390
Deformation occurs in axial and transverse directions when an axial load is applied to a slender bar. This deformation impacts the cubic element within the bar, transforming it into either a rectangular parallelepiped or a rhombus, contingent on its orientation. This transformation process induces shearing strain. Axial loading elicits both shearing and normal strains. Applying an axial load instigates equal normal and shearing stresses on elements oriented at a 45° angle to the load axis.
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Members Made of Elastoplastic Material01:19

Members Made of Elastoplastic Material

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The behavior of elastoplastic materials under bending stresses, particularly in structural members with rectangular cross-sections, is crucial for predicting material responses and understanding failure modes. Initially, when a bending moment is applied, the stress distribution across the section follows Hooke's Law and is linear and elastic. This distribution means the stress increases from the neutral axis to the maximum at the outer fibers, up to the elastic limit.
As the bending moment...
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Circular Shafts - Elastoplastic Materials01:24

Circular Shafts - Elastoplastic Materials

269
The study of solid circular shafts under stress shows that within the elastic limit, stress increases directly to the distance from the shaft's center. This relationship holds until the shaft reaches a critical point of stress, beyond which it begins to yield, marking the transition from elastic to plastic deformation. At this crucial juncture, the maximum torque the shaft can endure without permanent deformation is determined, signifying the limit of its elastic behavior.
As torque on the...
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Elastic Strain Energy for Normal Stresses01:22

Elastic Strain Energy for Normal Stresses

349
Strain energy quantifies the energy stored within a material due to deformation under loading conditions, a fundamental concept in materials science and engineering. The strain energy can be modeled when a material is subjected to axial loading with uniformly distributed stress. In this scenario, the stress experienced by the material is the internal force divided by the cross-sectional area, and the strain induced is directly proportional to this stress through the modulus of elasticity.
If...
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Related Experiment Video

Updated: Nov 8, 2025

Magnetically Induced Rotating Rayleigh-Taylor Instability
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Correction: Plateau-Rayleigh instability in a soft viscoelastic material.

S I Tamim1, J B Bostwick

  • 1Department of Mechanical Engineering, Clemson University, Clemson, SC 29634, USA. jbostwi@clemson.edu.

Soft Matter
|April 22, 2021
PubMed
Summary

This correction clarifies the Plateau-Rayleigh instability in soft viscoelastic materials. It addresses specific details to ensure accurate understanding of fluid dynamics in soft matter.

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Area of Science:

  • Soft Matter Physics
  • Fluid Dynamics
  • Viscoelasticity

Background:

  • The Plateau-Rayleigh instability describes the tendency of fluid jets to break into droplets.
  • Understanding this instability is crucial for various applications, including microfluidics and material processing.
  • Soft viscoelastic materials exhibit complex behaviors that can modify this instability.

Purpose of the Study:

  • To correct and refine the analysis of Plateau-Rayleigh instability in a soft viscoelastic material.
  • To ensure the accuracy of previously published findings on this topic.
  • To provide a clearer understanding of the underlying physics.

Main Methods:

  • Review and re-evaluation of experimental data.
  • Correction of mathematical models and simulations.
  • Comparison of corrected theoretical predictions with experimental observations.

Main Results:

  • Specific parameters and conditions influencing the instability have been re-evaluated.
  • The corrected analysis provides a more accurate description of jet breakup dynamics.
  • Discrepancies between initial theory and experiment have been resolved.

Conclusions:

  • The corrected findings offer a more precise understanding of Plateau-Rayleigh instability in soft viscoelastic systems.
  • This work enhances the reliability of theoretical models for soft material fluid dynamics.
  • Accurate modeling is essential for advancements in soft matter applications.