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Plastic Deformations01:19

Plastic Deformations

Plastic deformation represents a fundamental concept in materials science, which explains the irreversible change in the shape of a material when it experiences stress beyond its elastic capability. This phenomenon is important in structural engineering, especially in designing and analyzing cantilever beams—structures that are securely fixed at one end and bear loads at the opposite end. When these beams are subjected to loads within their elastic range, they will return to their original...
Plastic Deformations01:14

Plastic Deformations

It is essential to understand how structural members behave under plastic deformation when the bending stress exceeds the material's yield strength. This state of deformation permanently alters the shape of the member, in contrast to the linear elastic behavior observed before yielding. The strain at any point in the member is expressed in terms of maximum strain. Notably, the neutral axis, which coincides with the centroid during elastic bending, shifts away from the centroid under plastic...
Temperature Dependent Deformation01:12

Temperature Dependent Deformation

In a nonhomogeneous rod made up of steel and brass, restrained at both ends and subjected to a temperature change, several steps are involved in calculating the stress and compressive load. Due to the problem's static indeterminacy, one end support is disconnected, allowing the rod to experience the temperature change freely. Next, an unknown force is applied at the free end, triggering deformations in the rod's steel and brass portions. These deformations are then calculated and added together...
Plasticity00:58

Plasticity

Plasticity is the property where an object loses its elasticity and undergoes irreversible deformation, even after the deformation forces are eliminated. If a material deforms irreversibly without increasing stress or load, then this is called ideal plasticity. For example, when a force is applied to an aluminum rod, it changes its shape, but it does not return to its original shape once the force is removed. Plastic deformation or ductility is thus a permanent deformation or change in the...
Plastic Behavior01:21

Plastic Behavior

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 reloaded.
Deformations in a Symmetric Member in Bending01:18

Deformations in a Symmetric Member in Bending

When analyzing the deformation of a symmetric prismatic member subjected to bending by equal and opposite couples, it becomes clear that as the member bends, the originally straight lines on its wider faces curve into circular arcs, with a constant radius centered at a point known as Point C. This phenomenon helps to understand the stress and strain distribution within the member more clearly.
When the member is segmented into tiny cubic elements, it is observed that the primary stress...

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関連する実験動画

Updated: Jul 11, 2026

Determining the Mechanical Strength of Ultra-Fine-Grained Metals
05:04

Determining the Mechanical Strength of Ultra-Fine-Grained Metals

Published on: November 22, 2021

材料科学:極端な物質の変形

R Lakes

    Science (New York, N.Y.)
    |September 11, 2007
    PubMed
    まとめ
    この要約は機械生成です。

    一部の材料は伸縮時に膨張し,負のポアソン比を示します. 泡とイオンプラズマで観察されるこの異常な性質は,不圧縮性につながる可能性があり,変形時に一定体積を維持します.

    さらに関連する動画

    High-pressure, High-temperature Deformation Experiment Using the New Generation Griggs-type Apparatus
    12:30

    High-pressure, High-temperature Deformation Experiment Using the New Generation Griggs-type Apparatus

    Published on: April 3, 2018

    Synthesis and Microdiffraction at Extreme Pressures and Temperatures
    07:26

    Synthesis and Microdiffraction at Extreme Pressures and Temperatures

    Published on: October 7, 2013

    関連する実験動画

    Last Updated: Jul 11, 2026

    Determining the Mechanical Strength of Ultra-Fine-Grained Metals
    05:04

    Determining the Mechanical Strength of Ultra-Fine-Grained Metals

    Published on: November 22, 2021

    High-pressure, High-temperature Deformation Experiment Using the New Generation Griggs-type Apparatus
    12:30

    High-pressure, High-temperature Deformation Experiment Using the New Generation Griggs-type Apparatus

    Published on: April 3, 2018

    Synthesis and Microdiffraction at Extreme Pressures and Temperatures
    07:26

    Synthesis and Microdiffraction at Extreme Pressures and Temperatures

    Published on: October 7, 2013

    科学分野:

    • マテリアルサイエンス 材料科学
    • 物理 物理学 物理学とは

    背景:

    • ほとんどの材料は,伸縮すると横断面で収縮します.
    • 泡のような一部の材料は,伸縮時に横方向に膨張し,オキセティックな行動を示します.
    • この現象の特徴は,負のプアソン比率である.

    研究 の 目的:

    • 材料における負のポアソン比率の起源について議論する.
    • この性質がイソトロピク材料とアニソトロピク材料の両方に与える影響を調査する.
    • 負のポアソン比率を持つ材料で不圧縮性を証明する研究を強調する.

    主な方法:

    • 文献レビューと理論的議論.
    • 異なる種類の材料における補助的行動の分析.
    • イオンプラズマの実験データの検討.

    主要な成果:

    • 負のポアソン比率を持つ材料は,不圧縮性を示すことができます.
    • この行動は,中性子星の殻からイオンプラズマまで,極端な密度の物質に予測されています.
    • イオンプラズマを用いた実験的検証は,理論的な予測を裏付けている.

    結論:

    • 負のポアソン比は,材料の非圧縮性を可能にする重要な性質です.
    • 補助材料は,そのユニークな変形特性により,さまざまな分野で潜在的な応用があります.
    • アクセティック材料に関するさらなる研究は,新しいエンジニアリングの可能性を開拓する可能性があります.