crystallitic

简明释义

英[ˌkrɪstəˈlɪtɪk]美[ˌkrɪstəˈlɪtɪk]

adj. 微晶的

英英释义

单词用法

同义词

反义词

例句

1.Brief introduction the composition about the flatness measurement instrument of the crystallitic vitreous panel. It is introduced to disposal to the measured data.

介绍自动检测微晶玻璃板材平面度装置的基本组成设备和检测数据的处理方法。

2.Brief introduction the elements about the flatness measurement instrument of the crystallitic vitreous panel. It is introduced to what to form and the arts and crafts process.

简介微晶玻璃板材平面度测试仪测试板材平面度的原理与组成的基本设备和测试的工艺过程。

3.Brief introduction the elements about the flatness measurement instrument of the crystallitic vitreous panel. It is introduced to what to form and the arts and crafts process.

简介微晶玻璃板材平面度测试仪测试板材平面度的原理与组成的基本设备和测试的工艺过程。

4.The crystallitic texture of the glassy material contributed to its unique optical properties.

该玻璃材料的结晶状纹理使其具有独特的光学特性。

5.In geology, the crystallitic fabric of a rock can provide insights into its cooling history.

在地质学中，岩石的结晶状构造可以提供关于其冷却历史的见解。

6.Researchers found that the crystallitic nature of the rock influenced its weathering patterns.

研究人员发现，该岩石的结晶状特性影响了其风化模式。

7.The mineral sample exhibited a distinct crystallitic structure, indicating its formation under specific temperature conditions.

该矿物样本显示出明显的结晶状结构，表明它是在特定温度条件下形成的。

8.The study focused on the crystallitic phases formed during the crystallization process.

该研究集中于结晶过程中形成的结晶状相。

作文

The study of minerals and their properties is a fascinating field that encompasses various disciplines, including geology, chemistry, and physics. One important aspect of mineralogy is the structure and formation of minerals, which can be understood through the concept of crystallinity. In this context, the term crystallitic refers to the crystalline structure of a mineral that is composed of numerous small crystals or grains. These crystallitic structures are often observed in igneous and metamorphic rocks, where the cooling rates of molten material can lead to the formation of distinct crystal patterns.When we examine a rock sample, we can often identify its crystallitic nature by observing the size and arrangement of the crystals within it. For instance, rocks that cool rapidly, such as basalt, tend to have a fine-grained crystallitic texture because the crystals do not have enough time to grow large. In contrast, slower cooling processes, as seen in granite, allow for larger crystals to form, resulting in a more coarse-grained crystallitic texture.The crystallitic structure of minerals plays a significant role in determining their physical properties, such as hardness, cleavage, and optical characteristics. For example, minerals with a well-defined crystallitic structure often exhibit perfect cleavage, allowing them to break along specific planes. This property is crucial for identifying minerals and understanding their uses in various applications, including construction, electronics, and jewelry.Moreover, the crystallitic nature of a mineral can influence its behavior under different environmental conditions. For instance, the presence of water can affect the stability of certain crystallitic structures, leading to processes such as weathering and erosion. Understanding these processes is essential for geologists and environmental scientists as they study the impact of natural forces on our planet.In addition to its geological significance, the concept of crystallitic structures has implications in other fields, such as materials science and engineering. Researchers often explore crystallitic materials for their unique properties, which can be harnessed for innovative technologies. For example, the development of advanced ceramics relies heavily on the manipulation of crystallitic structures to achieve desired mechanical and thermal properties.In conclusion, the term crystallitic encapsulates a vital aspect of mineralogy that reflects the intricate relationship between a mineral's structure and its properties. By studying crystallitic structures, scientists can gain insights into the formation and behavior of minerals, which ultimately enhances our understanding of the Earth and its resources. As we continue to explore the complexities of minerals and their crystallitic characteristics, we open doors to new discoveries and advancements in various scientific domains.

矿物及其特性的研究是一个迷人的领域，涵盖了地质学、化学和物理学等多个学科。矿物学的一个重要方面是矿物的结构和形成，这可以通过结晶度的概念来理解。在这个背景下，术语crystallitic指的是由许多小晶体或颗粒组成的矿物的晶体结构。这些crystallitic结构通常在火成岩和变质岩中观察到，其中熔融材料的冷却速度会导致不同的晶体图案形成。当我们检查一块岩石样本时，通常可以通过观察其中的晶体大小和排列来识别其crystallitic特性。例如，快速冷却的岩石，如玄武岩，往往具有细粒的crystallitic纹理，因为晶体没有足够的时间生长得很大。相比之下，慢速冷却的过程，如花岗岩，允许形成较大的晶体，从而产生更粗糙的crystallitic纹理。矿物的crystallitic结构在确定其物理特性（如硬度、解理和光学特性）方面起着重要作用。例如，具有明确的crystallitic结构的矿物通常表现出完美的解理，使它们沿特定平面断裂。这一特性对于识别矿物和理解其在建筑、电子和珠宝等各种应用中的用途至关重要。此外，矿物的crystallitic特性也会影响其在不同环境条件下的行为。例如，水的存在可以影响某些crystallitic结构的稳定性，导致风化和侵蚀等过程。理解这些过程对地质学家和环境科学家至关重要，因为他们研究自然力量对我们星球的影响。除了其地质学意义外，crystallitic结构的概念在材料科学和工程等其他领域也具有重要意义。研究人员常常探索crystallitic材料的独特特性，这些特性可以被利用于创新技术。例如，先进陶瓷的发展在很大程度上依赖于对crystallitic结构的操控，以实现所需的机械和热性能。总之，术语crystallitic概括了矿物学的一个重要方面，反映了矿物结构与其特性之间错综复杂的关系。通过研究crystallitic结构，科学家可以深入了解矿物的形成和行为，从而增强我们对地球及其资源的理解。随着我们继续探索矿物及其crystallitic特性的复杂性，我们为新的发现和各个科学领域的进步打开了大门。