anelastic

简明释义

英[ˌænɪˈlæstɪk]美[ænɪˈlæstɪk]

adj. 滞弹（性）的

英英释义

单词用法

同义词

反义词

例句

1.This paper derives an energy attenuation formula of seismic waves in the wavelet-scale domain from the wavelet theory and seismic wave propagation equation in anelastic medium.

本文从小波理论出发，结合地震波在黏弹性介质中的传播方程，推导出小波尺度域地震波能量衰减公式。

2.During the transient creep after stress decrease, it has been found that the total strain transient consists of two components, elastic strain and anelastic strain.

当外加应力突然降低后，在瞬时蠕变过程中发生了弹性应变和滞弹性应变，整个降载过程中的应变变化值与应力变化值成线性关系。

3.The combined effects of soft rock sites and anelastic attenuation factor have been separated and determined respectively by (using) this method.

采用该方法，分离软基岩场地联合效应和非弹性衰减的影响，并把二者分别确定出来。

4.The mechanism of anelastic creep of polycrystalline copper at higher temperatures may thus be considered to be similar to...

因此，可以认为多晶纯铜在较高温度下的滞弹性蠕变机构与晶粒间界自扩散机构相似。

5.Objective: to prepare anelastic hydrochloride nasal spray and to study its stability.

目的观察双氯芬酸钾喷雾剂的抗炎镇痛作用。

6.Objective: To prepare anelastic hydrochloride nasal spray and to study its stability.

目的：制备盐酸氮?汀鼻喷雾剂，并进行稳定性考察。

7.The material displayed anelastic behavior under high stress, meaning it did not return to its original shape after deformation.

该材料在高应力下表现出无弹性行为，意味着它在变形后无法恢复到原来的形状。

8.An anelastic response can lead to unexpected failures in structural components over time.

无弹性响应可能导致结构组件随着时间的推移出现意外故障。

9.When subjected to continuous stress, the metal showed anelastic behavior, indicating a permanent change in shape.

在持续应力作用下，该金属表现出无弹性行为，表明形状发生了永久性变化。

10.In engineering applications, understanding anelastic properties is crucial for predicting the long-term performance of materials.

在工程应用中，理解无弹性特性对于预测材料的长期性能至关重要。

11.The researchers noted that the rubber exhibited anelastic characteristics at elevated temperatures.

研究人员指出，橡胶在高温下表现出无弹性特征。

作文

The study of materials and their properties is crucial in various fields, including engineering, physics, and materials science. One interesting property that some materials exhibit is known as 非弹性. Unlike elastic materials that return to their original shape after being deformed, 非弹性 materials do not fully recover their shape once the applied stress is removed. This behavior can be observed in various substances, such as certain polymers and metals when subjected to specific conditions.For instance, consider a rubber band, which is a classic example of an elastic material. When you stretch it, it elongates, but once you release it, it returns to its original form. In contrast, if you take a piece of clay and mold it into a shape, it will retain that new shape even after the force is removed. This characteristic demonstrates the 非弹性 nature of clay. Understanding this distinction is essential for engineers who need to select appropriate materials for specific applications.In construction, for example, the choice between using elastic and 非弹性 materials can significantly affect the durability and safety of structures. Elastic materials might be preferred for components that require flexibility and resilience, such as bridges and roadways that experience constant movement and stress. However, in situations where permanent deformation is acceptable or even advantageous, 非弹性 materials may be utilized, such as in certain types of insulation or soundproofing.Furthermore, the concept of 非弹性 is not limited to physical materials alone. It can also be applied metaphorically to various aspects of life and society. For instance, consider the rigidity of certain social systems or cultural norms that do not adapt or change despite external pressures. These systems can be seen as 非弹性 in nature, resisting transformation and remaining fixed in their ways, much like a material that does not return to its original state after deformation.In conclusion, the understanding of 非弹性 materials and their properties is vital across various disciplines. Whether in the realm of physical sciences or in the analysis of social constructs, recognizing the implications of 非弹性 allows for better decision-making and innovative approaches to problem-solving. As we continue to explore the complexities of materials and their behaviors, the concept of 非弹性 will undoubtedly remain a significant focus of study and application.

材料及其特性的研究在工程、物理和材料科学等多个领域中至关重要。一些材料所表现出的有趣特性被称为非弹性。与在变形后能恢复到原始形状的弹性材料不同，非弹性材料在施加的应力去除后不会完全恢复其形状。这种行为可以在一些物质中观察到，例如某些聚合物和金属在特定条件下。例如，考虑橡皮筋，这是一个经典的弹性材料示例。当你拉伸它时，它会变长，但一旦你放开它，它就会恢复到原来的形状。相反，如果你拿一块粘土并将其塑造成一种形状，即使施加的力量被移除，它也会保持这种新形状。这种特性展示了粘土的非弹性特征。理解这一区别对工程师选择适当材料以满足特定应用至关重要。在建筑中，例如，在使用弹性和非弹性材料之间的选择可能会显著影响结构的耐久性和安全性。弹性材料可能更适合用于需要灵活性和韧性的组件，例如经历持续运动和压力的桥梁和道路。然而，在某些情况下，永久变形是可以接受甚至有利的，非弹性材料可能会被利用，例如在某些类型的绝缘或隔音中。此外，非弹性的概念不仅限于物理材料。它也可以隐喻性地应用于生活和社会的各个方面。例如，考虑某些社会制度或文化规范的僵化，这些制度或规范尽管受到外部压力却不适应或改变。这些系统可以被视为非弹性的，自我抵抗转型，保持固定的方式，就像一种在变形后不会恢复到原始状态的材料。总之，理解非弹性材料及其特性在各个学科中都是至关重要的。无论是在物理科学领域还是在对社会构造的分析中，认识到非弹性的含义能够更好地进行决策并创新性地解决问题。随着我们继续探索材料及其行为的复杂性，非弹性的概念无疑将继续成为研究和应用的重要焦点。