aeolotropic
简明释义
英[ˌiːələʊˈtrɒpɪk]美[ˌerəˈtrɑpɪk]
adj. [物] 各向异性的;有方向性的;非均质的
英英释义
Relating to or exhibiting properties that vary based on direction, particularly in the context of materials or physical phenomena. | 与方向相关或表现出基于方向变化的特性,特别是在材料或物理现象的背景下。 |
单词用法
各向异性行为 | |
各向异性材料 | |
各向异性应力 | |
各向异性效应 |
同义词
| 各向异性 | Anisotropic materials exhibit different properties in different directions. | 各向异性材料在不同方向上表现出不同的特性。 | |
| 方向性 | Directional dependence is crucial in the study of wave propagation. | 方向依赖性在波传播研究中至关重要。 |
反义词
例句
1.For the study of birefringence dispersion character of other aeolotropic crystal material, this method can also be applied.
此方法对其它各向异性晶体材料的双折射率色散特性的研究同样适应。
2.For the study of birefringence dispersion character of other aeolotropic crystal material, this method can also be applied.
此方法对其它各向异性晶体材料的双折射率色散特性的研究同样适应。
3.Understanding the aeolotropic behavior of the soil is crucial for foundation design.
理解土壤的各向异性行为对基础设计至关重要。
4.In geology, many rock formations are aeolotropic, affecting how they respond to stress.
在地质学中,许多岩层是各向异性的,这影响了它们对应力的反应。
5.The mechanical properties of the material are aeolotropic, meaning they vary depending on the direction of the applied force.
材料的机械性能是各向异性的,这意味着它们会根据施加力的方向而变化。
6.The aeolotropic nature of the fabric allows it to stretch more in one direction than the other.
这种织物的各向异性特性使其在一个方向上比另一个方向更能拉伸。
7.When designing composite materials, engineers must consider their aeolotropic properties to ensure optimal performance.
在设计复合材料时,工程师必须考虑其各向异性特性,以确保最佳性能。
作文
In the realm of material science and engineering, understanding the properties of materials is crucial for innovation and application. One such property that often comes into play is the concept of aeolotropic, which refers to materials that exhibit different physical or mechanical properties when measured along different axes. This characteristic is particularly significant in the study of composite materials, crystals, and biological tissues. For instance, wood is a classic example of an aeolotropic material; it is stronger and stiffer along the grain than across it. This anisotropic behavior must be taken into account when designing structures that rely on wood as a primary material.The implications of aeolotropic properties extend beyond just wood. In the field of geology, rocks can also display aeolotropic characteristics, where their strength and deformation behavior vary with direction due to their mineral composition and structure. Understanding these properties is essential for civil engineers who design foundations and structures that interact with these geological materials. If an engineer fails to consider the aeolotropic nature of a rock formation, the resulting structure could be at risk of failure under load.Moreover, in the world of polymers and composites, aeolotropic behavior plays a pivotal role in determining the performance of materials under stress. Many advanced materials are designed to be aeolotropic deliberately, allowing for tailored properties that meet specific application needs. For example, aerospace engineers often use carbon fiber composites that are aeolotropic, providing high strength-to-weight ratios while ensuring flexibility where needed.The concept of aeolotropic also finds its way into the biological sciences. Tissues in living organisms often exhibit aeolotropic properties, which are critical for their function. Muscles, tendons, and ligaments are structured in a way that provides strength and flexibility in the directions they are most needed. Understanding the aeolotropic nature of these biological materials has important implications for medicine, particularly in fields like orthopedics and rehabilitation, where the mechanical properties of tissues inform treatment strategies and surgical techniques.In conclusion, the term aeolotropic encompasses a fundamental aspect of material behavior that is essential for various fields, including engineering, geology, and biology. Recognizing and analyzing the aeolotropic nature of materials allows scientists and engineers to make informed decisions in design and application, ensuring safety and efficiency in their respective fields. As we continue to innovate and push the boundaries of technology, a deep understanding of aeolotropic materials will undoubtedly lead to advancements that improve our everyday lives and the world around us.
在材料科学和工程领域,理解材料的性质对于创新和应用至关重要。其中一个经常出现的概念是aeolotropic,指的是在不同轴向测量时表现出不同物理或机械性质的材料。这一特性在复合材料、晶体和生物组织的研究中尤为重要。例如,木材就是一个经典的aeolotropic材料的例子;它在纹理方向上比横向更强、更硬。在设计依赖木材作为主要材料的结构时,必须考虑这种各向异性的行为。aeolotropic特性的影响不仅限于木材。在地质学领域,岩石也可能显示出aeolotropic特性,其强度和变形行为因矿物成分和结构的不同而有所变化。理解这些特性对于土木工程师设计与这些地质材料相互作用的基础和结构至关重要。如果工程师未能考虑岩层的aeolotropic特性,所建结构可能在负载下面临失效风险。此外,在聚合物和复合材料的世界中,aeolotropic行为在确定材料在应力下的性能方面发挥着关键作用。许多先进材料被故意设计为aeolotropic,以便提供满足特定应用需求的定制属性。例如,航空航天工程师经常使用碳纤维复合材料,这些材料具有aeolotropic特性,提供高强度与重量比,同时确保在需要的地方具备灵活性。aeolotropic的概念还进入了生物科学领域。生物体内的组织通常表现出aeolotropic特性,这对其功能至关重要。肌肉、肌腱和韧带的结构方式提供了在最需要的方向上的强度和灵活性。理解这些生物材料的aeolotropic特性对医学具有重要意义,特别是在骨科和康复等领域,其中组织的机械特性为治疗策略和外科技术提供了信息。总之,aeolotropic一词涵盖了材料行为的基本方面,这对于工程、地质和生物等多个领域都是至关重要的。识别和分析材料的aeolotropic特性使科学家和工程师能够在设计和应用中做出明智的决策,从而确保其各自领域的安全性和效率。随着我们不断创新并推动技术的边界,对aeolotropic材料的深刻理解无疑将导致改善我们日常生活和周围世界的进步。
