metallization
简明释义
英[ˌmetəlaɪˈzeɪʃən]美[metəlaɪˈzeɪʃən]
n. [材] 金属化;敷金属;[机] 金属喷镀
英英释义
单词用法
表面的金属化 | |
电解金属化 | |
金属化的物理气相沉积 | |
金属化中的化学气相沉积 | |
薄膜金属化 | |
金属化层 | |
金属化过程 | |
金属化方法 |
同义词
| 金属涂层 | The metal coating provides a protective layer against corrosion. | 金属涂层提供了防腐蚀的保护层。 | |
| 金属化过程 | The metallization process is crucial in electronics manufacturing. | 金属化过程在电子制造中至关重要。 | |
| 金属化 | 金属化表面可以增强其导电性。 |
反义词
例句
1.One aspect of the present invention is a method of forming a semiconductor device having copper metallization.
本发明的一个方面是形成具有铜金属化的半导体器件的方法。
2.The relationship between metallization rate and reducibility is analyzed based onthe definitions of them.
根据金属化率和还原度的定义,分析了二者之间的关系。
3.Therefore gold metallization is accompanied with potassic alteration, silication and alkali granite.
金矿化总是与钾化、硅化交代或碱性花岗岩共生。
4.The metallization is controlled by the Permian volcanic lithofacies and volcanic edifice.
其成矿作用主要受二叠纪火山岩相及火山机构控制。
5.The diopside is not of certain relation to the metallization.
某些矿床中发育的纯透辉石层与成矿不具必然联系。
6.So Yongping copper ore deposit possessed the derivation characteristics of metallization.
永平铜矿床具明显的衍生成矿特点。
7.The metallization of plastics can enhance their durability and aesthetic appeal.
塑料的金属化可以增强它们的耐用性和美观性。
8.The process of metallization is essential for improving the conductivity of certain materials.
金属化过程对于提高某些材料的导电性至关重要。
9.In the electronics industry, metallization is used to create connections on circuit boards.
在电子行业,金属化用于在电路板上创建连接。
10.Researchers are exploring new methods of metallization to improve solar cell efficiency.
研究人员正在探索新的金属化方法以提高太阳能电池的效率。
11.The metallization technique used in this study significantly reduces production costs.
本研究中使用的金属化技术显著降低了生产成本。
作文
The process of metallization is an essential aspect of modern technology, particularly in the fields of electronics and materials science. Metallization refers to the application of a metallic layer onto a substrate, which can be made of various materials such as glass, plastic, or silicon. This technique is crucial for creating conductive pathways in electronic devices, enhancing their functionality and efficiency. For example, in the manufacturing of solar panels, metallization plays a vital role in improving the electrical conductivity of the cells, allowing them to convert sunlight into electricity more effectively.In addition to electronics, metallization is also widely used in decorative applications. The process can give objects a shiny, metallic finish, making them visually appealing. This is commonly seen in jewelry, automotive parts, and various consumer products where aesthetics are important. The ability to create a metallic appearance without using solid metals allows manufacturers to reduce costs while still providing high-quality finishes.Moreover, the metallization process can enhance the durability and corrosion resistance of materials. By applying a thin layer of metal, products can better withstand environmental factors such as moisture, heat, and chemicals. This is particularly beneficial in industries like aerospace and automotive, where performance and longevity are critical. For instance, aircraft components often undergo metallization to ensure they remain robust and reliable under extreme conditions.The methods of metallization can vary significantly depending on the desired outcome and the materials involved. Common techniques include physical vapor deposition (PVD), chemical vapor deposition (CVD), and electroplating. Each method has its advantages and limitations, making it important for engineers and scientists to choose the appropriate technique based on the specific requirements of their projects.As technology continues to advance, the applications of metallization are evolving as well. Researchers are exploring new materials and methods that could lead to even more efficient and effective metallization processes. For example, the development of nanotechnology has opened up new possibilities for metallization, allowing for the creation of ultra-thin metallic layers that can significantly improve the performance of electronic devices.In conclusion, metallization is a fundamental process that impacts various industries, from electronics to aesthetics. Its ability to enhance conductivity, improve durability, and provide attractive finishes makes it a valuable technique in modern manufacturing. As we move forward, the ongoing research and innovation in metallization will likely lead to even more exciting developments, further integrating this process into our daily lives and advancing technology as a whole.
“金属化”过程是现代科技的一个重要方面,特别是在电子和材料科学领域。“金属化”指的是在基材上施加金属层,这些基材可以由玻璃、塑料或硅等多种材料制成。这项技术对于在电子设备中创建导电路径至关重要,从而提高它们的功能性和效率。例如,在太阳能电池板的制造中,“金属化”在提高电池的电导率方面发挥着重要作用,使其能够更有效地将阳光转化为电能。除了电子产品外,“金属化”也广泛应用于装饰性用途。该过程可以使物体具有光亮的金属表面,从而使其视觉上更具吸引力。这在珠宝、汽车零件和各种消费者产品中常见,其中美学非常重要。能够创造出金属外观而不使用固体金属,使制造商能够降低成本,同时仍提供高质量的表面处理。此外,“金属化”过程还可以增强材料的耐用性和抗腐蚀性。通过施加一层薄薄的金属,产品可以更好地抵御环境因素,如湿气、热量和化学品。这在航空航天和汽车等行业尤其有益,因为性能和耐久性至关重要。例如,飞机部件通常会经过“金属化”处理,以确保它们在极端条件下保持坚固和可靠。“金属化”的方法可能因所需结果和所涉及材料的不同而显著变化。常见的技术包括物理气相沉积(PVD)、化学气相沉积(CVD)和电镀。每种方法都有其优点和局限性,因此工程师和科学家必须根据项目的具体要求选择适当的技术。随着科技的不断进步,“金属化”的应用也在不断演变。研究人员正在探索新材料和方法,这可能导致更高效和更有效的金属化过程。例如,纳米技术的发展为“金属化”开辟了新的可能性,允许创建超薄金属层,从而显著改善电子设备的性能。总之,“金属化”是影响各个行业的基本过程,从电子产品到美学。其增强导电性、改善耐久性和提供吸引人外观的能力,使其成为现代制造中的一种宝贵技术。随着我们向前发展,“金属化”领域的持续研究和创新可能会带来更多令人兴奋的发展,将这一过程进一步融入我们的日常生活,并推动科技整体进步。
