pulling of crystals

简明释义

直拉单晶

英英释义

例句

1.The scientist explained the process of pulling of crystals to create pure silicon for semiconductors.

科学家解释了为了制造纯硅半导体而进行的晶体拉伸过程。

2.In the lab, we observed the pulling of crystals from a saturated solution.

在实验室中，我们观察到从饱和溶液中进行的晶体拉伸。

3.The pulling of crystals technique is essential in the production of high-quality gemstones.

在高品质宝石的生产中，晶体拉伸技术至关重要。

4.The pulling of crystals method allows for the growth of larger and more uniform crystals.

通过晶体拉伸方法，可以生长出更大且更均匀的晶体。

5.During the workshop, participants learned about the pulling of crystals and its applications in materials science.

在研讨会上，参与者学习了晶体拉伸及其在材料科学中的应用。

作文

The process of crystal growth is a fascinating subject that has intrigued scientists and researchers for decades. One of the most important techniques in this field is the pulling of crystals, which refers to the method of growing single crystals by slowly pulling them from a molten or vapor phase. This technique is not only crucial for understanding the fundamental properties of materials but also plays a significant role in various industrial applications. In essence, the pulling of crystals involves carefully controlling the temperature and environment in which the crystals form. By doing so, researchers can influence the size, purity, and structural integrity of the crystals. For instance, in the semiconductor industry, high-purity silicon crystals are essential for manufacturing electronic components. The pulling of crystals allows for the production of these high-quality materials, which are vital for the performance of modern technology.Moreover, the pulling of crystals is not limited to silicon alone. This technique is used to grow various types of crystals, including those made from metals, salts, and even organic compounds. Each type of crystal has its unique properties and applications. For example, quartz crystals, which are often grown using the pulling of crystals method, are widely used in the production of watches and clocks due to their piezoelectric properties.The importance of the pulling of crystals extends beyond industrial applications; it is also critical in scientific research. Researchers study the growth patterns and characteristics of crystals to understand fundamental principles of chemistry and physics. By analyzing how different conditions affect the pulling of crystals, scientists can gain insights into molecular interactions and material behaviors at the atomic level.Furthermore, advancements in technology have improved the pulling of crystals process. Innovations in automation and precision measurement allow for better control over the growth conditions, leading to more uniform and defect-free crystals. This progress is essential for meeting the increasing demands of industries that rely on high-performance materials.In conclusion, the pulling of crystals is a vital process in both industry and research. It enables the production of high-quality materials essential for technology and provides valuable insights into the nature of matter. As we continue to advance in this field, the implications of the pulling of crystals will undoubtedly expand, leading to new discoveries and innovations that could shape the future of materials science and engineering.

晶体生长的过程是一个迷人的主题，几十年来吸引了科学家和研究人员的关注。在这个领域中，最重要的技术之一是晶体拉制，它指的是通过从熔融或气相中缓慢拉出单晶体来生长单晶体的方法。这一技术不仅对于理解材料的基本性质至关重要，而且在各种工业应用中也发挥着重要作用。本质上，晶体拉制涉及到仔细控制晶体形成的温度和环境。通过这样做，研究人员可以影响晶体的大小、纯度和结构完整性。例如，在半导体行业，高纯度的硅晶体对于制造电子元件至关重要。晶体拉制使得这些高质量材料的生产成为可能，这对现代技术的性能至关重要。此外，晶体拉制并不限于硅。这一技术用于生长各种类型的晶体，包括金属、盐类甚至有机化合物制成的晶体。每种类型的晶体都有其独特的性质和应用。例如，石英晶体通常采用晶体拉制方法生长，由于其压电特性，广泛用于手表和时钟的生产。晶体拉制的重要性不仅限于工业应用；它在科学研究中也至关重要。研究人员研究晶体的生长模式和特性，以理解化学和物理的基本原理。通过分析不同条件如何影响晶体拉制，科学家可以深入了解分子相互作用和物质在原子层面的行为。此外，技术的进步改善了晶体拉制过程。自动化和精密测量的创新使得对生长条件的控制更加精确，从而导致更均匀且无缺陷的晶体的产生。这一进展对于满足依赖高性能材料的行业日益增长的需求至关重要。总之，晶体拉制是工业和研究中一项至关重要的过程。它使得生产高质量材料成为可能，这些材料对技术至关重要，并提供了对物质本质的宝贵见解。随着我们在这一领域的不断进步，晶体拉制的影响无疑将扩展，导致新的发现和创新，这可能会塑造材料科学和工程的未来。