crystallization

简明释义

英[ˌkrɪstəlaɪˈzeɪʃ(ə)n]美[ˌkrɪstələˈzeɪʃn]

n. 结晶化；具体化

英英释义

单词用法

同义词

反义词

例句

1.In color like water drops in the crystallization of emotional sigh.

在水珠般的色彩里凝聚着情感的叹息。

2.This results agree with that of isothermal crystallization kinetics.

这一结果同等温结晶相一致。

3.Crystallization organization fine plating, its protective performance and appearance quality is more ideal.

结晶组织较细的镀层，其防护性能和外观质量都较理想。

4.It has spindly fibers that protrude from the atomic vertices like spokes, and they interfere with crystallization.

它拥有细长的纤维像辐条一样从原子顶部凸出并且干涉其结晶。

5.And this reaction is what we call crystallization.

这个反应我们称为结晶。

6.Because this metal crystal is in the cathodic reduction of the form, it is called the electricity crystallization.

因为这种金属晶体是在阴极还原的情况下形成的，故称之电结晶。

7.The process of crystallization 结晶 is essential in the production of high-quality sugar.

结晶的过程在高质量糖的生产中至关重要。

8.In chemistry, crystallization 结晶 helps purify compounds by separating them from impurities.

在化学中，结晶有助于通过将化合物与杂质分开来纯化化合物。

9.The crystallization 结晶 of salt from seawater is a natural process that has been used for centuries.

海水中的盐的结晶是一个自然过程，已经被使用了几个世纪。

10.After cooling the solution, we observed the crystallization 结晶 of sugar on the bottom of the container.

冷却溶液后，我们观察到糖在容器底部的结晶。

11.The crystallization 结晶 of minerals can create beautiful formations in caves.

矿物的结晶可以在洞穴中形成美丽的构造。

作文

The process of crystallization is one of the most fascinating phenomena in nature and science. It refers to the formation of solid crystals from a homogeneous solution or melt. This process can be observed in various contexts, from the formation of snowflakes in the atmosphere to the creation of sugar crystals in a kitchen. Understanding crystallization not only helps us appreciate the beauty of nature but also has significant implications in fields such as chemistry, geology, and material science. In chemistry, crystallization is often used as a purification technique. When a solution contains impurities, cooling it down allows the desired substance to form solid crystals, leaving the impurities dissolved in the liquid. This method is essential in laboratories and industries where high purity is required. For instance, the pharmaceutical industry relies heavily on crystallization to produce pure compounds for medications, ensuring that patients receive safe and effective treatments. Moreover, crystallization plays a crucial role in geology. The Earth's crust is composed of various minerals, many of which are formed through crystallization processes over millions of years. When magma cools and solidifies, minerals crystallize out of the molten rock, leading to the formation of igneous rocks. Similarly, sedimentary rocks can form when dissolved minerals precipitate out of water, creating beautiful crystalline structures. Understanding these geological processes helps scientists reconstruct the Earth's history and understand its dynamic nature. In addition to its scientific importance, crystallization has aesthetic value. The intricate patterns and structures of crystals have inspired artists, architects, and designers throughout history. From the delicate symmetry of a snowflake to the dazzling formations of gemstones, the beauty of crystallization is evident in many aspects of art and culture. Artists often draw inspiration from the geometric shapes and vibrant colors of crystals, creating works that celebrate the natural world. Furthermore, crystallization can be observed in everyday life. When we cook, we often encounter this process without even realizing it. For example, when making candy, we dissolve sugar in water and then allow it to cool. As the solution cools, sugar molecules begin to come together and form solid crystals, resulting in delicious treats like rock candy. This practical application of crystallization illustrates how scientific principles can be integrated into our daily activities, making them both enjoyable and educational. In conclusion, the process of crystallization is a remarkable phenomenon that encompasses various aspects of science, art, and daily life. Its significance extends beyond mere aesthetics, as it plays a vital role in purification techniques, geological formations, and even culinary practices. By understanding crystallization, we gain insight into the natural world and the intricate processes that shape it. Whether we admire the beauty of a crystal or benefit from its applications in technology and medicine, the impact of crystallization is profound and far-reaching.

结晶过程是自然和科学中最迷人的现象之一。它指的是从均匀溶液或熔体中形成固体晶体的过程。这一过程可以在各种环境中观察到，从大气中的雪花形成到厨房中的糖晶体制作。理解结晶化不仅有助于我们欣赏自然之美，而且在化学、地质和材料科学等领域具有重要意义。 在化学中，结晶化通常用作一种纯化技术。当溶液中含有杂质时，冷却它可以使所需物质形成固体晶体，而将杂质留在液体中。这种方法在实验室和工业中至关重要，因为高纯度是必需的。例如，制药行业高度依赖结晶化来生产用于药物的纯化合物，以确保患者获得安全有效的治疗。 此外，结晶化在地质学中也起着关键作用。地壳由各种矿物组成，许多矿物是在数百万年间通过结晶化过程形成的。当岩浆冷却并固化时，矿物从熔融岩石中结晶出来，形成火成岩。同样，当溶解的矿物从水中沉淀出来时，也可以形成沉积岩，创造出美丽的晶体结构。理解这些地质过程有助于科学家重建地球的历史并理解其动态特性。 除了科学重要性之外，结晶化还具有美学价值。晶体的复杂图案和结构激励了艺术家、建筑师和设计师在历史上创作。从雪花的精致对称性到宝石的璀璨形态，结晶化的美在艺术和文化的许多方面都显而易见。艺术家们常常从晶体的几何形状和鲜艳色彩中汲取灵感，创作出庆祝自然世界的作品。 此外，结晶化在日常生活中也可以观察到。当我们烹饪时，常常在不知不觉中遇到这个过程。例如，在制作糖果时，我们将糖溶解在水中，然后让其冷却。当溶液冷却时，糖分子开始聚集并形成固体晶体，最终得到美味的摇糖。这种对结晶化的实际应用说明了科学原理如何融入我们的日常活动，使其既愉快又富有教育意义。 总之，结晶化的过程是一种非凡的现象，涵盖了科学、艺术和日常生活的各个方面。它的重要性超越了单纯的美学，因为它在纯化技术、地质形成甚至烹饪实践中发挥着至关重要的作用。通过理解结晶化，我们获得了对自然世界及其塑造过程的深入了解。无论我们是欣赏晶体的美丽，还是从其在技术和医学中的应用中受益，结晶化的影响都是深远而广泛的。