monoclinic system

简明释义

单斜晶系

英英释义

例句

1.When studying the symmetry of crystals, we often refer to the monoclinic system 单斜晶系 as a key example.

在研究晶体的对称性时，我们常常将单斜晶系 monoclinic system 作为一个关键示例。

2.In mineralogy, the monoclinic system 单斜晶系 includes minerals like orthoclase and jadeite.

在矿物学中，单斜晶系 monoclinic system 包括正长石和翡翠等矿物。

3.The monoclinic system 单斜晶系 can be identified by its distinct axial relationships and angles.

可以通过其独特的轴关系和角度来识别单斜晶系 monoclinic system。

4.The unique properties of the monoclinic system 单斜晶系 allow for specific optical behaviors in certain crystals.

单斜晶系 monoclinic system 的独特性质使某些晶体表现出特定的光学行为。

5.The crystal structure of gypsum belongs to the monoclinic system 单斜晶系, which is characterized by three unequal axes with one angle different from 90 degrees.

石膏的晶体结构属于单斜晶系 monoclinic system，其特征是三个不等的轴，其中一个角不同于90度。

作文

The study of crystallography reveals a fascinating world where the arrangement of atoms dictates the properties of materials. Among the various crystal systems, the monoclinic system stands out due to its unique characteristics and significance in both scientific research and industrial applications. Understanding the monoclinic system not only enhances our knowledge of material science but also opens doors to innovations in technology and manufacturing.The monoclinic system is one of the seven crystal systems in crystallography, defined by three unequal axes, with one of them inclined to the other two. This unique geometric arrangement results in a variety of crystal shapes, such as prisms and plates. The angles between the axes are not right angles, which distinguishes the monoclinic system from other systems like the cubic or tetragonal systems. The most common minerals that crystallize in the monoclinic system include gypsum, orthoclase, and clinopyroxene, each exhibiting distinct physical properties that can be attributed to their crystal structures.One of the key aspects of the monoclinic system is its role in determining the physical properties of materials. For instance, the anisotropic nature of monoclinic crystals means that their properties vary depending on the direction of measurement. This characteristic is crucial in fields such as optics and electronics, where directional properties can significantly influence performance. Researchers often explore the monoclinic system to develop new materials with tailored properties for specific applications, such as piezoelectric devices or advanced optical components.In addition to its theoretical importance, the monoclinic system has practical implications in various industries. For example, in the field of ceramics, understanding the crystal structure of monoclinic materials can lead to the development of stronger and more durable products. The ability to manipulate the properties of monoclinic ceramics through controlled processing techniques can result in improved performance in high-temperature environments, making them ideal for applications in aerospace and automotive industries.Furthermore, the monoclinic system is also significant in the realm of geology. Many minerals found in the Earth's crust crystallize in this system, providing valuable insights into geological processes and conditions. By studying the formation and transformation of monoclinic minerals, geologists can better understand the history of rock formations and the environmental conditions under which they developed.In conclusion, the monoclinic system represents a crucial component of crystallography with far-reaching implications in science and industry. Its unique structural attributes and the resulting anisotropic properties make it a focal point for research and development across various fields. As we continue to explore the intricacies of the monoclinic system, we can expect to uncover new materials and technologies that will shape the future of multiple industries. The ongoing study of this crystal system not only enriches our understanding of material properties but also paves the way for innovative solutions to contemporary challenges in technology and engineering.

晶体学的研究揭示了一个迷人的世界，在这个世界里，原子的排列决定了材料的特性。在各种晶体系统中，单斜晶系因其独特的特性和在科学研究与工业应用中的重要性而脱颖而出。理解单斜晶系不仅增强了我们对材料科学的认识，还为技术和制造业的创新打开了大门。单斜晶系是晶体学中七个晶体系统之一，由三个不等的轴定义，其中一个轴倾斜于其他两个。这种独特的几何排列导致了多种晶体形状，例如棱柱和板。轴之间的角度不是直角，这使得单斜晶系与立方晶系或四方晶系等其他系统有所区别。常见的在单斜晶系中结晶的矿物包括石膏、正长石和铬铁矿，每种矿物都展现出可以归因于其晶体结构的独特物理特性。单斜晶系的一个关键方面是其在决定材料物理特性中的作用。例如，单斜晶体的各向异性特征意味着它们的属性会根据测量方向的不同而变化。这一特性在光学和电子学等领域至关重要，因为方向特性可以显著影响性能。研究人员经常探索单斜晶系以开发具有特定应用所需的定制属性的新材料，例如压电设备或先进的光学元件。除了理论上的重要性，单斜晶系在各个行业中也具有实际意义。例如，在陶瓷领域，理解单斜材料的晶体结构可以导致更强大和更耐用产品的发展。通过控制加工技术来操控单斜陶瓷的特性，可以在高温环境中提高性能，使其成为航空航天和汽车工业中理想的应用材料。此外，单斜晶系在地质学领域也具有重要意义。许多在地壳中发现的矿物都是在这一系统中结晶的，为地质过程和条件提供了宝贵的见解。通过研究单斜矿物的形成和转化，地质学家可以更好地理解岩石形成的历史及其发展所处的环境条件。总之，单斜晶系代表了晶体学的一个关键组成部分，对科学和工业具有深远的影响。其独特的结构特征和由此产生的各向异性特性使其成为多个领域研究和发展的重点。随着我们继续探索单斜晶系的复杂性，我们可以期待发现新的材料和技术，这些材料和技术将塑造多个行业的未来。对这一晶体系统的持续研究不仅丰富了我们对材料特性的理解，也为解决当代技术和工程挑战铺平了道路。