aeolotropy

简明释义

[ˌiːəˈlɒtrəpi][ˌiːəˈlɒtrəpi]

[物] 各向异性

英英释义

Aeolotropy refers to the property of certain materials that exhibit different physical properties in different directions, particularly in relation to their response to wind or air movement.

风向性是指某些材料在不同方向上表现出不同的物理特性,特别是与其对风或空气运动的反应有关。

单词用法

同义词

wind directionality

风向性

The study of aeolotropy is essential in understanding how wind directionality affects sediment transport.

研究风向性对于理解风对沉积物运输的影响至关重要。

aeolian processes

风成过程

Aeolian processes play a significant role in shaping desert landscapes, which is a key aspect of aeolotropy.

风成过程在塑造沙漠景观中起着重要作用,这是风向性的一个关键方面。

反义词

isotropy

各向同性

In isotropy, physical properties are the same in all directions.

在各向同性中,物理性质在所有方向上都是相同的。

homogeneity

均匀性

The material's homogeneity ensures consistent performance across different applications.

材料的均匀性确保在不同应用中的一致性能。

例句

1.The metal in the graphite substrate can not only improve the aeolotropy of graphite radiation, but also facilitate the overall radiation of the material.

石墨基体中的金属能改善石墨材料散热的各向异性,提 高材料的整体散热性能。

2.The metal in the graphite substrate can not only improve the aeolotropy of graphite radiation, but also facilitate the overall radiation of the material.

石墨基体中的金属能改善石墨材料散热的各向异性,提 高材料的整体散热性能。

3.The study of aeolotropy reveals how certain materials can exhibit different properties based on their orientation.

风向性的研究揭示了某些材料如何根据其方向展现不同的特性。

4.In geophysics, aeolotropy is crucial for understanding seismic wave propagation in the Earth's crust.

在地球物理学中,风向性对于理解地壳中地震波传播至关重要。

5.Researchers are exploring the aeolotropy of certain minerals to improve material design in engineering.

研究人员正在探索某些矿物的风向性,以改善工程材料设计。

6.Understanding aeolotropy is essential for predicting how buildings will respond to wind forces.

理解风向性对于预测建筑物如何应对风力至关重要。

7.The aeolotropy of the fabric affects how it drapes and moves when worn.

这种织物的风向性影响它穿着时的垂坠感和运动方式。

作文

In the realm of science, particularly in geology and material science, the term aeolotropy refers to the directional dependence of properties or behaviors in materials. This concept is crucial for understanding how certain materials respond to various forces and environmental conditions. For instance, when a rock is subjected to stress, its response may vary depending on the direction of that stress due to its internal structure. This characteristic can significantly influence the stability and durability of geological formations, which is why it is essential for engineers and geologists to consider aeolotropy when assessing the integrity of structures built on or within these materials.The significance of aeolotropy extends beyond geology; it plays a vital role in the field of engineering, particularly in the design of buildings, bridges, and other structures. Engineers must take into account the directional properties of the materials they use to ensure that their designs can withstand the forces applied to them. For example, concrete is often treated as an isotropic material, meaning it has uniform properties in all directions. However, when reinforced with steel, the resulting composite material exhibits aeolotropy, as the steel reinforcement provides strength primarily in one direction. Understanding this behavior allows engineers to optimize their designs for safety and efficiency.Moreover, aeolotropy can also be observed in biological materials. For instance, wood is a natural material that exhibits pronounced aeolotropy due to its fibrous structure. The strength and flexibility of wood vary significantly between the longitudinal and transverse directions. This property is why wood is often chosen for specific applications, such as construction and furniture making, where its directional strength can be utilized effectively. By recognizing the aeolotropy of wood, craftsmen can create stronger and more durable products.In addition to its practical applications, the study of aeolotropy also opens up new avenues for research and innovation. Scientists are continually exploring materials that exhibit unique aeolotropy to develop advanced technologies. For example, the emergence of smart materials that can change their properties based on external stimuli relies heavily on understanding how aeolotropy can be manipulated. These materials have the potential to revolutionize industries by providing solutions that adapt to changing conditions, enhancing performance and functionality.In conclusion, aeolotropy is a fundamental concept that permeates various fields, from geology to engineering and biology. Its implications are vast, influencing the way we design, construct, and utilize materials in our daily lives. As we continue to advance in technology and scientific understanding, recognizing and harnessing the principles of aeolotropy will undoubtedly lead to more innovative and resilient solutions in the future. Understanding this concept not only enriches our knowledge of material properties but also empowers us to make informed decisions in both practical and theoretical applications.

风化性是一个科学领域,特别是在地质学和材料科学中,指的是材料在不同方向上属性或行为的方向性依赖性。这个概念对于理解某些材料如何响应各种力量和环境条件至关重要。例如,当岩石受到应力时,其响应可能会因应力的方向而异,这取决于其内部结构。这个特性可以显著影响地质构造的稳定性和耐久性,这就是为什么工程师和地质学家在评估建造在这些材料上的结构的完整性时必须考虑风化性风化性的重要性不仅限于地质学;它在工程领域中也发挥着重要作用,特别是在建筑、桥梁和其他结构的设计中。工程师必须考虑他们使用的材料的方向性特性,以确保他们的设计能够承受施加于它们的力量。例如,混凝土通常被视为各向同性材料,意味着它在所有方向上具有均匀的性能。然而,当与钢筋一起使用时,所得到的复合材料表现出风化性,因为钢筋主要提供一个方向上的强度。理解这种行为使工程师能够优化他们的设计,以确保安全和效率。此外,风化性还可以在生物材料中观察到。例如,木材是一种天然材料,由于其纤维结构而表现出明显的风化性。木材的强度和柔韧性在纵向和横向之间有显著差异。这种特性是木材常常被选择用于特定应用(如建筑和家具制造)的原因,因为它的方向强度可以有效利用。通过认识到木材的风化性,工匠可以创造出更强大和耐用的产品。除了实际应用之外,风化性的研究也为研究和创新开辟了新的途径。科学家们不断探索表现出独特风化性的材料,以开发先进技术。例如,智能材料的出现可以根据外部刺激改变其属性,这在很大程度上依赖于对如何操控风化性的理解。这些材料有潜力通过提供适应变化条件的解决方案来革新行业,提高性能和功能。总之,风化性是一个基本概念,渗透到各个领域,从地质学到工程学和生物学。它的影响广泛,影响着我们设计、建造和利用日常生活中的材料的方式。随着我们在技术和科学理解上的不断进步,认识和利用风化性的原理无疑将导致未来更具创新性和抗压性的解决方案。理解这一概念不仅丰富了我们对材料特性的知识,还赋予我们在实际和理论应用中做出明智决策的能力。