anelasticity是一个物理学概念,指的是材料在受到外力作用时,内部应力与应变之间的关系。具体来说,当材料受到外力作用时,其内部会产生应力,而应力的大小和方向取决于外力的大小和方向以及材料的性质。如果材料内部存在缺陷或结构不均匀,那么应力分布也会受到影响。因此,anelasticity研究的是材料内部应力的分布和变化规律,以及如何通过优化材料结构和性能来减小应力的影响。
发音:/??n??sel?ks?t?/
英语范文:Anelasticity plays a crucial role in ensuring the safety and reliability of many engineering structures. Understanding the relationship between external forces and internal stress is essential for designing structures that are resilient to unexpected loads and deformation. By optimizing the material properties and structural design, engineers can minimize the effects of anelasticity and ensure that their structures are safe and reliable in all conditions.
音标和基础释义:(注:音标为英文音标,用中文谐音标注)
音标:[??n?s?l?ksi]
释义:anelasticity(无) 弹性不均匀性(材料在受到外力作用时,内部应力与应变之间的关系)在工程结构中起着至关重要的作用。了解外部力和内部应力之间的关系对于设计能够抵抗意外载荷和变形的结构至关重要。通过优化材料属性和结构设计,工程师可以最小化anelasticity的影响并确保他们的结构在所有条件下都是安全和可靠的。
anelasticity是一个物理学中的概念,指的是当材料受到外部扰动时,其内部应力的变化与扰动量之间的比值。它可以用于研究材料在受到地震、温度变化等外部扰动时的响应。
发音:/?'ne?sl??k?t?/
英语范文:
标题:Anelasticity and Material Response
Anelasticity is a fundamental concept in materials science that describes how materials respond to external disturbances. When a material is subjected to an external force or temperature change, its internal stress changes and this change is proportional to the magnitude of the disturbance. Understanding anelasticity is crucial in studying materials that are subjected to external stresses, such as in earthquake engineering or in materials used in high-temperature environments.
In my research, I have studied the response of different materials to anelasticity. I have found that certain materials respond differently to external stresses, and this has implications for their use in different applications. For instance, certain materials may be more suitable for use in structures that need to withstand high levels of stress, while others may be more suitable for use in environments with low temperatures or high temperatures.
In conclusion, anelasticity is an essential concept in materials science that helps us understand the response of materials to external stresses. Understanding this concept is crucial for developing materials that are suitable for different applications and environments.
Anelasticity is a term used in physics and engineering to describe the change in a material's properties when subjected to a change in stress or strain. In other words, it measures the response of a material to a change in its external environment.
If we consider a material that is under stress, and this stress is then reduced, we would expect the material to return to its original state, with some deformation or strain. This deformation or strain is known as the elastic response of the material. However, if the stress is removed and the material remains deformed, then we can say that there has been anelasticity present in the material.
In engineering applications, anelasticity is important because it can affect the performance of structures and systems. For example, if a bridge or building is built using materials with anelasticity, then the structure may experience changes in its shape over time due to changes in external loads or environmental conditions. This can lead to reduced performance and safety concerns.
To address these concerns, engineers need to understand the magnitude and nature of anelasticity present in their materials and structures, and how it can be controlled or minimized. This requires a combination of experimental and computational methods, including testing and modeling of materials and structures, as well as analysis of their response to various external stimuli.
In summary, anelasticity is a fundamental property of materials that can have significant impacts on the performance and safety of structures and systems. Understanding and controlling anelasticity is essential for ensuring safe and reliable engineering designs.
