silane

简明释义

英['sɪleɪn]美[ˈsɪlˌeɪn]

n. [无化][电子] 硅烷；矽烷

英英释义

单词用法

同义词

反义词

例句

1.The interfacial effects of silane coupling between asphalt with granite and cement mortar were studied in this paper.

研究了硅烷偶联剂对沥青与石料及水泥砂浆界面的作用。

2.In some cases, leaks of silane will not ignite immediately.

在某些情况下，泄露的硅烷不会立刻点燃。

3.Similarly, using silane in the way the FBR process was designed, carbon and oxygen are not introduced.

同样，在使用过程中的快堆设计，碳和氧硅烷的方法是没有介绍。

4.If the silane has no polar group, the surface free energy is low.

反之若硅烷中不含有极性基，则处理后玻纤的表面能较低。

5.The thickness of the incubation layer increases with increasing silane concentration and decreasing discharge power.

孵化层的厚度随硅烷浓度的增加或辉光功率的降低而增大。

6.Water reacts with the silane forming silanol groups.

水与硅烷反应形成硅醇基因。

7.The reaction of silane with oxygen produces silicon dioxide.

硅烷与氧气反应生成二氧化硅。

8.In the semiconductor industry, silane is often used as a precursor for silicon deposition.

在半导体行业中，硅烷常用作硅沉积的前驱体。

9.The chemical formula for silane is SiH₄.

化学式为硅烷的化合物是SiH₄。

10.Safety precautions should be taken when handling silane due to its flammability.

处理硅烷时应采取安全预防措施，因为它易燃。

11.Researchers are exploring the use of silane in enhancing the durability of materials.

研究人员正在探索使用硅烷来增强材料的耐久性。

作文

Silane is a chemical compound that plays a crucial role in various industries, particularly in the fields of materials science and chemistry. It is composed of silicon and hydrogen, with the general formula SiH₄. The significance of silane (硅烷) lies not only in its unique properties but also in its diverse applications. For instance, silane (硅烷) is often used as a coupling agent in the production of composite materials. By enhancing the bond between organic and inorganic materials, it improves the overall strength and durability of products such as plastics and ceramics.In addition to its role in composites, silane (硅烷) is also utilized in the semiconductor industry. As technology advances, the need for smaller and more efficient electronic components has increased. Silane (硅烷) serves as a precursor for the deposition of silicon thin films, which are essential for the fabrication of various electronic devices including solar cells and transistors. This application demonstrates how silane (硅烷) contributes to the innovation of modern technology.Moreover, silane (硅烷) compounds have been studied for their potential in the field of nanotechnology. Researchers are exploring the use of silane (硅烷) to create functionalized surfaces at the nanoscale. By modifying surfaces with silane (硅烷), scientists can enhance properties such as hydrophobicity or biocompatibility, leading to advancements in medical devices and coatings.The synthesis of silane (硅烷) is another area of interest. Traditionally, silane (硅烷) is produced through the reaction of silicon with hydrogen gas. However, researchers are continuously looking for more efficient and environmentally friendly methods of production. Innovations in this field could lead to a decrease in production costs and a reduction in environmental impact, making silane (硅烷) even more appealing for industrial use.Despite its many advantages, handling silane (硅烷) requires caution due to its flammable nature. Safety protocols must be followed to prevent accidents during its storage and usage. This highlights the importance of proper training and awareness in industries that utilize silane (硅烷) to ensure the safety of workers and the environment.In conclusion, silane (硅烷) is a versatile compound with significant implications across various sectors. Its ability to enhance material properties, contribute to technological advancements, and potentially improve production methods makes it a subject of ongoing research and development. As we continue to explore the capabilities of silane (硅烷), it is evident that this compound will play an integral role in shaping the future of materials science and technology.

硅烷是一种化合物，在多个行业中扮演着重要角色，特别是在材料科学和化学领域。它由硅和氢组成，通式为SiH₄。硅烷的意义不仅在于其独特的性质，还在于其多样的应用。例如，硅烷常用作复合材料生产中的偶联剂。通过增强有机和无机材料之间的结合，它提高了塑料和陶瓷等产品的整体强度和耐久性。除了在复合材料中的作用外，硅烷还被用于半导体行业。随着技术的发展，对更小、更高效的电子元件的需求不断增加。硅烷作为硅薄膜沉积的前驱体，对于各种电子设备的制造至关重要，包括太阳能电池和晶体管。这一应用展示了硅烷如何推动现代技术的创新。此外，硅烷化合物在纳米技术领域也受到研究者的关注。研究人员正在探索使用硅烷在纳米尺度上创建功能化表面。通过用硅烷修饰表面，科学家们可以增强疏水性或生物相容性，从而推动医疗设备和涂层的进步。硅烷的合成也是一个值得关注的领域。传统上，硅烷是通过硅与氢气反应生成的。然而，研究人员不断寻找更高效和环保的生产方法。该领域的创新可能会导致生产成本的降低和环境影响的减少，使硅烷在工业应用中更加具有吸引力。尽管具有许多优点，但由于硅烷的易燃性，处理时需要谨慎。在存储和使用过程中必须遵循安全协议，以防止事故的发生。这突显了在利用硅烷的行业中，适当培训和意识的重要性，以确保工人和环境的安全。总之，硅烷是一种多用途的化合物，对各个领域都有重要影响。它能够增强材料性能、促进技术进步，并有可能改善生产方法，使其成为持续研究和开发的主题。随着我们继续探索硅烷的能力，显然这种化合物将在塑造材料科学和技术的未来中扮演不可或缺的角色。