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Three-Dimensional Analysis of Strain01:29

Three-Dimensional Analysis of Strain

273
Three-dimensional strain analysis is crucial for understanding how materials deform under stress, particularly in elastic, homogeneous materials. This method employs principal stress axes to simplify complex stress states into more understandable forms. Subjected to stress, a small cubic element within a material either expands or contracts along these axes, transforming into a rectangular parallelepiped. This transformation effectively illustrates the material's deformation. The principal...
273
Transformation of Plane Strain01:12

Transformation of Plane Strain

221
When analyzing elongated structures like bars subjected to uniformly distributed loads, it is essential to understand the transformation of plane strain when coordinate axes are rotated. This transformation helps to assess how material deformation characteristics vary with orientation, which is crucial in materials science and structural engineering.
Under plane strain conditions, typical for members where one dimension significantly exceeds the others, deformations and resultant strains are...
221
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

310
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.
310
Measurements of Strain01:27

Measurements of Strain

1.8K
Strain quantifies the deformation of a material under force, typically measured as normal strain, which represents the change in length when compared with the original length. Electrical strain gauges are used for enhanced accuracy. These devices consist of a conductive wire mounted on a paper backing that adheres to the material's surface. These gauges operate on the piezoresistive effect, where the wire's electrical resistance changes in response to mechanical deformation. The strain...
1.8K
Generalized Hooke's Law01:22

Generalized Hooke's Law

1.2K
The generalized Hooke's Law is a broadened version of Hooke's Law, which extends to all types of stress and in every direction. Consider an isotropic material shaped into a cube subjected to multiaxial loading. In this scenario, normal stresses are exerted along the three coordinate axes. As a result of these stresses, the cubic shape deforms into a rectangular parallelepiped. Despite this deformation, the new shape maintains equal sides, and there is a normal strain in the direction of the...
1.2K
Normal Strain under Axial Loading01:20

Normal Strain under Axial Loading

606
Normal strain under axial loading is an important concept in the field of mechanics of materials. Axial loading implies the application of a force along the axis of a material, like a column or bar. This force can either compress or stretch the material. In the context of axial loading, normal strain is the deformation experienced by the material in the direction of the loading force. It's calculated as the change in length divided by the original length of the material. This unitless ratio...
606

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Related Experiment Video

Updated: Aug 12, 2025

High-resolution Imaging of Nuclear Dynamics in Live Cells under Uniaxial Tensile Strain
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High-resolution Imaging of Nuclear Dynamics in Live Cells under Uniaxial Tensile Strain

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Tunable biaxial strain device for low-dimensional materials.

Vincent Pasquier1, Alessandro Scarfato1, Jose Martinez-Castro1

  • 1DQMP, Université de Genève, 24 Quai Ernest Ansermet, CH-1211 Geneva, Switzerland.

The Review of Scientific Instruments
|February 1, 2023
PubMed
Summary

Researchers developed a compact device for applying uniform biaxial strain to 2D materials. This innovation enables controlled property tuning in materials like molybdenum disulfide (MoS2) without sacrificing uniformity or reversibility.

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Area of Science:

  • Materials Science
  • Condensed Matter Physics
  • Nanotechnology

Background:

  • Strain engineering is crucial for tuning the properties of 2D materials and heterostructures.
  • Existing biaxial strain devices often compromise on maximum strain, uniformity, or size.

Purpose of the Study:

  • To present a novel, compact device for applying uniform in-plane biaxial strain to 2D materials.
  • To demonstrate performance and uniformity comparable to larger devices.

Main Methods:

  • Finite Element Analysis (FEA) for modeling strain distribution and uniformity.
  • Raman spectroscopy to measure the response of exfoliated 2H-molybdenum disulfide (MoS2) to applied strain.

Main Results:

  • The compact device achieves high uniformity and significant maximum strain.
  • FEA modeling accurately predicted device performance.
  • Experimental results confirmed the controlled application of biaxial strain on MoS2.

Conclusions:

  • The developed device offers a practical solution for controlled biaxial strain application in 2D materials.
  • This facilitates advanced research in strain-tunable electronic and optical properties of nanomaterials.