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相关概念视频

Deformation of Member under Multiple Loadings01:11

Deformation of Member under Multiple Loadings

163
When a rod is made of different materials or has various cross-sections, it must be divided into parts that meet the necessary conditions for determining the deformation. These parts are each characterized by their internal force, cross-sectional area, length, and modulus of elasticity. These parameters are then used to compute the deformation of the entire rod.
In the case of a member with a variable cross-section, the strain is not constant but depends on the position. The deformation of an...
163
Deformations in a Symmetric Member in Bending01:18

Deformations in a Symmetric Member in Bending

166
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...
166
Temperature Dependent Deformation01:12

Temperature Dependent Deformation

146
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...
146
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

261
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.
261
Deformation in a Circular Shaft01:10

Deformation in a Circular Shaft

276
One of the distinctive characteristics of circular shafts is their ability to maintain their cross-sectional integrity under torsion. In other words, each cross-section continues to exist as a flat, unaltered entity, simply rotating like a solid, rigid slab. To understand the distribution of shearing stress within such a shaft, consider a cylindrical section inside this circular shaft. This section has a length of L and a radius of R, with one end fixed. The radius of the cylindrical section is...
276
Plastic Deformation in Circular Shafts01:20

Plastic Deformation in Circular Shafts

184
When materials are subjected to forces that surpass their yield strength, they undergo a process known as plastic deformation. This results in a permanent alteration or strain in their structure. This concept can be specifically applied to circular shafts, where the deformation leads to a change in its shape. The precise evaluation of this plastic deformation requires understanding the stress distribution within the circular shaft, which is achieved by calculating the maximum shearing stress in...
184

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相关实验视频

Updated: Jun 20, 2025

Micro/Nano-scale Strain Distribution Measurement from Sampling Moiré Fringes
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Micro/Nano-scale Strain Distribution Measurement from Sampling Moiré Fringes

Published on: May 23, 2017

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在循环变形下脱位随机行走.

Atsushi Kubo1, Emi Kawai1, Takashi Sumigawa2

  • 1Institute of Industrial Science, The University of Tokyo, 4-6-1 Komaba, Meguro-ku, Tokyo 153-8505, Japan.

Physical review. E
|July 18, 2024
PubMed
概括

这项研究引入了一种随机步行模型,用于预测循环负荷下的脱位扩散. 该模型准确地估计了脱位扩散系数,通过铜分子动力学模拟验证.

更多相关视频

Theoretical Calculation and Experimental Verification for Dislocation Reduction in Germanium Epitaxial Layers with Semicylindrical Voids on Silicon
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Comprehensive Characterization of Extended Defects in Semiconductor Materials by a Scanning Electron Microscope
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相关实验视频

Last Updated: Jun 20, 2025

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Comprehensive Characterization of Extended Defects in Semiconductor Materials by a Scanning Electron Microscope
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科学领域:

  • 材料科学 材料科学 材料科学
  • 凝聚物质物理学 凝聚物质物理学
  • 计算材料科学科学 计算材料科学

背景情况:

  • 脱位运动对于理解循环负荷下的材料行为至关重要.
  • 现有的模型可能无法完全捕捉出位动态的随机性质.
  • 准确预测脱位扩散对于疲劳寿命评估至关重要.

研究的目的:

  • 开发一种新型的随机步行模型,用于循环负荷下脱位扩散.
  • 通过分析推导出异位运动的扩散系数和概率分布.
  • 用分子动力学模拟来验证模型.

主要方法:

  • 将失位行为建模为一系列一维的随机步行 (二项式随机过程).
  • 每个循环的排位运动概率分布和扩散系数的分析推导.
  • 在周期变形下对铜的分子动力学模拟进行验证.

主要成果:

  • 在循环负荷下衍生出异位的扩散系数的分析方程.
  • 随机步行模型与分子动力学模拟结果有很好的一致性.
  • 该模型成功地将宏观负载条件与微观材料特性联系起来.

结论:

  • 开发的随机步行模型为循环负荷下脱位扩散提供了强大的理论框架.
  • 该模型的验证证实了其在预测材料对循环应激反应的有用性.
  • 这种方法为模拟位移动态提供了一个计算效率高的替代方案.