lamellation

简明释义

英[ˌlæməˈleɪʃən]美[ˌlæməˈleɪʃən]

n. 页理；薄层状

英英释义

单词用法

同义词

反义词

例句

1.The growth of structural fracture is controlled by such factors as lithology, porosity, lamellation and local structures, and the regional fracture controlled mainly by the regional stress field.

构造裂缝的发育受岩石本身的力学性质以及局部构造制约，区域裂缝则与区域应力场强度有关。

2.The growth of structural fracture is controlled by such factors as lithology, porosity, lamellation and local structures, and the regional fracture controlled mainly by the regional stress field.

构造裂缝的发育受岩石本身的力学性质以及局部构造制约，区域裂缝则与区域应力场强度有关。

3.The scientist studied the process of lamellation to understand how layers form in geological structures.

科学家研究了层状结构的过程，以了解地质结构中层是如何形成的。

4.During the lecture, the professor explained the importance of lamellation in the formation of sedimentary rocks.

在讲座中，教授解释了层状结构在沉积岩形成中的重要性。

5.The engineer focused on lamellation in materials science to improve the durability of composites.

工程师专注于材料科学中的层状结构，以提高复合材料的耐用性。

6.The artist used lamellation techniques to create depth in her paintings.

艺术家使用层状技术为她的画作创造深度。

7.In biology, lamellation is crucial for understanding the structure of certain plant leaves.

在生物学中，层状结构对理解某些植物叶子的结构至关重要。

作文

In the field of geology, the term lamellation refers to the process of forming thin layers or plates within rocks or minerals. This phenomenon can be observed in various geological formations and is a significant aspect of understanding the Earth's structure. The lamellation process often occurs due to the gradual deposition of materials over time, leading to the creation of distinct layers that can provide valuable information about the environmental conditions at the time of their formation.For instance, sedimentary rocks frequently exhibit lamellation as a result of the accumulation of sediments in bodies of water. These layers can vary in thickness, composition, and color, reflecting changes in the depositional environment. By studying these layers, geologists can reconstruct past climates, sea levels, and even biological activity. This ability to interpret geological history through lamellation is crucial for both academic research and practical applications, such as natural resource exploration.Moreover, lamellation is not limited to sedimentary rocks. It can also be found in metamorphic and igneous rocks, where the layering may result from different processes, such as the cooling of magma or the alteration of existing rock under heat and pressure. In metamorphic rocks, for example, lamellation can indicate the directional pressures that the rock has undergone, providing insights into tectonic activities and the geological history of an area.The study of lamellation extends beyond geology; it also finds relevance in materials science and engineering. Understanding how materials can be layered or laminated can lead to innovations in creating stronger, more durable products. For example, laminated composites are widely used in construction and manufacturing, where multiple layers of materials are bonded together to enhance performance characteristics.In biology, the concept of lamellation can also apply to cellular structures. Certain cells exhibit layered arrangements that are essential for their function. For instance, the lamellae in chloroplasts are critical for photosynthesis, where they house the necessary components for capturing light energy. This biological lamellation illustrates the importance of layered structures in various fields of study.In conclusion, the term lamellation encompasses a variety of processes and structures across different disciplines. Whether in geology, materials science, or biology, lamellation signifies the significance of layers in understanding complexity and functionality. As we continue to explore and study our world, the concept of lamellation will undoubtedly remain a vital aspect of our scientific endeavors, allowing us to uncover the intricacies of both natural and engineered systems.

在地质学领域，术语lamellation指的是在岩石或矿物中形成薄层或板的过程。这种现象可以在各种地质构造中观察到，是理解地球结构的重要方面。lamellation过程通常是由于材料随着时间的推移逐渐沉积而发生的，导致形成不同的层，这些层可以提供关于其形成时环境条件的宝贵信息。例如，沉积岩常常由于在水体中沉积物的积累而表现出lamellation。这些层的厚度、成分和颜色可能各不相同，反映了沉积环境的变化。通过研究这些层，地质学家可以重建过去的气候、海平面甚至生物活动。通过lamellation解读地质历史的能力对于学术研究和实际应用（如自然资源勘探）至关重要。此外，lamellation不仅限于沉积岩。在变质岩和火成岩中也可以发现它，其分层可能是由于不同的过程，例如岩浆冷却或在热和压力下改变现有岩石。在变质岩中，例如，lamellation可以指示岩石经历的方向性压力，为构造活动和某个地区的地质历史提供见解。对lamellation的研究超越了地质学；它在材料科学和工程中也具有相关性。理解材料如何分层或层压可以导致创造更强大、更耐用产品的创新。例如，层压复合材料广泛用于建筑和制造业，其中多层材料被粘合在一起以增强性能特征。在生物学中，lamellation的概念也可以应用于细胞结构。某些细胞表现出分层排列，这对其功能至关重要。例如，叶绿体中的层状结构对光合作用至关重要，在那里它们容纳捕获光能所需的组件。这种生物学上的lamellation说明了在各个研究领域中分层结构的重要性。总之，术语lamellation涵盖了不同学科中的多种过程和结构。无论是在地质学、材料科学还是生物学中，lamellation都代表着层次在理解复杂性和功能性方面的重要性。随着我们继续探索和研究我们的世界，lamellation的概念无疑将继续成为我们科学努力的重要方面，让我们揭示自然和工程系统的复杂性。