automorphic crystal

简明释义

自形晶;

英英释义

例句

1.In mineralogy, an automorphic crystal can form under specific environmental conditions that promote its growth.

在矿物学中，自同晶体可以在促进其生长的特定环境条件下形成。

2.The museum exhibit featured several types of automorphic crystals from different parts of the world.

博物馆展览展示了来自世界不同地区的几种类型的自同晶体。

3.The automorphic crystal displayed perfect edges and faces, making it a prized specimen for collectors.

这块自同晶体展现出完美的边缘和面，使其成为收藏家的珍贵标本。

4.The researcher discovered an automorphic crystal in the geological samples, which is known for its unique symmetry.

研究人员在地质样本中发现了一种自同晶体，以其独特的对称性而闻名。

5.Scientists are studying the properties of automorphic crystals to understand their potential applications in technology.

科学家们正在研究自同晶体的性质，以了解其在技术中的潜在应用。

作文

The world of crystallography is a fascinating realm where science and art converge. Among the various types of crystals, the term automorphic crystal refers to crystals that exhibit well-defined and characteristic external shapes that reflect their internal symmetry. Understanding automorphic crystal structures can provide valuable insights into not only the nature of the crystals themselves but also the processes that lead to their formation. Automorphic crystals are often recognized by their distinct geometric shapes, which can be seen in minerals such as quartz and calcite. These crystals grow in an environment where they have ample space to develop their unique forms. The term 'automorphic' comes from the Greek word 'auto,' meaning self, and 'morphe,' meaning shape. Therefore, automorphic crystal essentially translates to 'self-shaped crystal.' This characteristic is crucial because it indicates that the crystal has developed without interference from other surrounding materials. In nature, the formation of automorphic crystals is influenced by several factors including temperature, pressure, and the chemical composition of the environment. For instance, when the conditions are just right, a mineral can crystallize in a way that allows it to grow freely, leading to the development of its automorphic form. This process can be observed in igneous rocks, where cooling magma allows for the growth of large, well-formed crystals. The study of automorphic crystals is not only important for geologists but also for various industries. For example, in the field of electronics, certain automorphic crystals are used in the manufacturing of semiconductors. Their unique properties allow for efficient conduction of electricity, making them invaluable in modern technology. Furthermore, the aesthetic appeal of these crystals has led to their popularity in jewelry and decorative items, showcasing their beauty and complexity. Moreover, understanding the properties of automorphic crystals can aid in the development of new materials. Scientists are continuously exploring how the arrangement of atoms within these crystals can lead to innovative applications in fields such as nanotechnology and materials science. By mimicking the natural processes that lead to the formation of automorphic crystals, researchers hope to create synthetic versions that harness the same beneficial properties. In conclusion, the study of automorphic crystals reveals much about the natural world and our ability to utilize its resources. From their striking appearances to their practical applications, automorphic crystals serve as a bridge between the realms of science and art. As we continue to explore the mysteries of crystallography, the significance of automorphic crystals will undoubtedly remain at the forefront of research and innovation. Their ability to capture the essence of nature's beauty while providing functional benefits exemplifies the intricate relationship between structure and function in the material world.

晶体学的世界是一个科学与艺术交汇的迷人领域。在各种类型的晶体中，术语自动形晶体指的是表现出明确定义和特征外形的晶体，这些外形反映了它们内部的对称性。理解自动形晶体结构可以提供关于这些晶体本质的重要见解，同时也揭示导致其形成的过程。自动形晶体通常通过其独特的几何形状而被识别，这在石英和方解石等矿物中可以看到。这些晶体在环境中有充足的空间来发展其独特的形状。术语“自动形”源于希腊语中的“auto”，意为自我，以及“morphe”，意为形状。因此，自动形晶体基本上可以翻译为“自我形状的晶体”。这个特征至关重要，因为它表明该晶体在形成过程中没有受到周围其他材料的干扰。在自然界中，自动形晶体的形成受多种因素的影响，包括温度、压力和环境的化学成分。例如，当条件恰到好处时，一种矿物可以以一种方式结晶，使其自由生长，从而形成其自动形态。这一过程可以在火成岩中观察到，在那里冷却的岩浆允许大型、形状良好的晶体的生长。研究自动形晶体不仅对地质学家很重要，对各个行业也同样重要。例如，在电子领域，某些自动形晶体被用于半导体的制造。它们独特的性质使得电流的有效传导成为可能，使其在现代技术中不可或缺。此外，这些晶体的美学吸引力使其在珠宝和装饰品中受到欢迎，展示了它们的美丽和复杂性。此外，理解自动形晶体的特性可以帮助开发新材料。科学家们不断探索这些晶体内部原子的排列如何导致创新应用，涉及纳米技术和材料科学等领域。通过模仿导致自动形晶体形成的自然过程，研究人员希望创造出具有相同有益特性的合成版本。总之，研究自动形晶体揭示了自然世界及我们利用其资源的能力。从它们引人注目的外观到实用的应用，自动形晶体作为科学与艺术领域之间的桥梁。随着我们继续探索晶体学的奥秘，自动形晶体的重要性无疑将始终处于研究和创新的前沿。它们能够捕捉自然之美的本质，同时提供功能性利益，体现了物质世界中结构与功能之间的复杂关系。