electrodeposit

简明释义

[ɪˌlektrəʊdɪˈpɒzɪt][ɪˌlektrodɪˈpɑzɪt]

v. 电沉积

n. 电沉淀物

复 数 e l e c t r o d e p o s i t s

第 三 人 称 单 数 e l e c t r o d e p o s i t s

现 在 分 词 e l e c t r o d e p o s i t i n g

过 去 式 e l e c t r o d e p o s i t e d

过 去 分 词 e l e c t r o d e p o s i t e d

英英释义

A process in which a substance is deposited onto an electrode through electrolysis.

一种通过电解将物质沉积到电极上的过程。

The resulting layer or coating formed on the surface of the electrode as a result of this process.

由于该过程形成的电极表面上的结果层或涂层。

单词用法

electrodeposit metals

电沉积金属

electrodeposit a layer

电沉积一层

electrodeposit from a solution

从溶液中电沉积

electrodeposition process

电沉积过程

electrodeposit coating

电沉积涂层

electrodeposit technique

电沉积技术

同义词

electrodeposition

电沉积

Electrodeposition is widely used in the manufacturing of electronic components.

电沉积广泛应用于电子元件的制造。

galvanic deposition

电镀沉积

Galvanic deposition is a popular method for plating metals.

电镀沉积是一种流行的金属镀层方法。

electroforming

电成型

Electroforming allows for the creation of complex shapes from metal.

电成型可以从金属中创建复杂的形状。

反义词

dissolution

溶解

The metal can undergo dissolution in an acidic solution.

金属可以在酸性溶液中发生溶解。

decomposition

分解

The organic compound showed signs of decomposition when exposed to heat.

该有机化合物在加热时出现了分解的迹象。

例句

1.Chromium electrodeposit with high hardness, wearability, corrosion resistance and distinctive appearance was widely applied in electroplating sector.

镀铬层具有高硬度、耐磨、耐蚀和独特的外观,在电镀行业中应用广泛。

2.This system can deal with the difficulty of image processing and detection aroused by strong reflection of electrodeposit surface and meet the demand of practice manufacture.

该系统有效的解决了电镀工件表面的强反射光给图像处理和检测带来的困难,适于生产现场自动检测应用。

3.Properties and preparing process of tri layer films with Ag base coating, Ni electrodeposit, Sn Pb alloy for terminal electrode of multilayer chip inductor were described.

介绍了叠层片式电感三层端头电极即银基底电极、镍层、锡-铅合金镀层的性能及制备工艺。

4.This system can deal with the difficulty of image processing and detection aroused by strong reflection of electrodeposit surface and meet the demand of practice manufacture.

该系统有效的解决了电镀工件表面的强反射光给图像处理和检测带来的困难,适于生产现场自动检测应用。

5.To improve conductivity, we need to optimize the electrodeposit process parameters.

为了提高导电性,我们需要优化电沉积工艺参数。

6.Researchers are exploring new alloys that can be produced using electrodeposit techniques.

研究人员正在探索可以使用电沉积技术生产的新合金。

7.In the electronics industry, electrodeposit is used to create thin films for circuit boards.

在电子行业中,电沉积用于为电路板创建薄膜。

8.The quality of the electrodeposit layer can significantly affect the performance of electronic devices.

层的质量电沉积会显著影响电子设备的性能。

9.The process of electrodeposit involves the deposition of a material onto a substrate through electrochemical means.

电沉积的过程涉及通过电化学方法将材料沉积到基材上。

作文

Electrodeposition is a fascinating process that plays a crucial role in various industries, especially in electroplating and the creation of advanced materials. The term electrodeposit refers to the deposition of a substance onto an electrode through the application of an electric current. This technique is widely utilized for coating metal surfaces to enhance their properties, such as corrosion resistance, aesthetic appeal, and electrical conductivity. In this essay, we will explore the significance of electrodeposit processes, their applications, and the underlying principles that govern them.One of the primary applications of electrodeposit techniques is in the field of electroplating. Electroplating involves the deposition of a layer of metal onto a substrate, which can be made of a different metal or even plastic. This process not only improves the appearance of the object but also provides protection against wear and corrosion. For instance, a common application is the electroplating of jewelry with gold or silver, enhancing its visual appeal while preventing tarnishing. Similarly, car parts are often coated with chrome through electrodeposit methods to ensure durability and a shiny finish.Moreover, electrodeposit processes are essential in the electronics industry. The production of printed circuit boards (PCBs) relies heavily on these techniques. During PCB manufacturing, copper is deposited onto the board using electrodeposit methods, allowing for the creation of intricate circuits that enable electronic devices to function efficiently. This application highlights how electrodeposit technology is integral to modern electronics, contributing to the miniaturization and enhancement of electronic components.The underlying principle of electrodeposit involves the movement of ions in an electrolyte solution. When an electric current is applied, positive metal ions migrate towards the negatively charged electrode, where they gain electrons and reduce to form a solid metal layer. This process can be controlled by adjusting various parameters, such as current density, temperature, and the composition of the electrolyte solution. These factors influence the quality and characteristics of the electrodeposit, including its thickness, adhesion, and uniformity.In addition to its industrial applications, electrodeposit processes are also being explored in the field of nanotechnology. Researchers are investigating the use of electrodeposit techniques to create nanostructured materials with unique properties. These materials have potential applications in various fields, including medicine, energy storage, and environmental remediation. For example, nanostructured coatings produced by electrodeposit methods can enhance the performance of batteries and supercapacitors by increasing surface area and improving charge transfer efficiency.In conclusion, the process of electrodeposit is a vital technology that underpins many aspects of modern manufacturing and material science. Its ability to enhance the properties of materials through controlled deposition makes it invaluable in industries ranging from jewelry to electronics and beyond. As research continues to advance, the potential applications of electrodeposit techniques are likely to expand, paving the way for innovative solutions to contemporary challenges. Understanding and mastering the principles of electrodeposit will undoubtedly contribute to future technological advancements and the development of new materials that can meet the demands of a rapidly evolving world.

电沉积是一个迷人的过程,在各个行业中发挥着至关重要的作用,尤其是在电镀和先进材料的制造中。术语electrodeposit指的是通过施加电流将物质沉积到电极上。这种技术广泛用于金属表面的涂层,以增强其特性,如耐腐蚀性、美观性和电导率。在这篇文章中,我们将探讨electrodeposit过程的重要性、应用及其背后的基本原理。electrodeposit技术的主要应用之一是在电镀领域。电镀涉及将一层金属沉积到基材上,基材可以是不同的金属或甚至塑料。这个过程不仅改善了物体的外观,还提供了对磨损和腐蚀的保护。例如,一个常见的应用是用金或银电镀珠宝,增强其视觉吸引力,同时防止氧化。同样,汽车零件通常通过electrodeposit方法涂覆铬,以确保耐用性和光泽。此外,electrodeposit过程在电子行业中也是必不可少的。印刷电路板(PCB)的生产在很大程度上依赖于这些技术。在PCB制造过程中,铜通过electrodeposit方法沉积到电路板上,从而能够创建复杂的电路,使电子设备高效运行。这一应用突显了electrodeposit技术在现代电子产品中的重要性,促进了电子元件的小型化和性能提升。electrodeposit的基本原理涉及电解液中离子的移动。当施加电流时,正金属离子向带负电的电极迁移,在那里它们获得电子并还原形成固态金属层。通过调整各种参数,如电流密度、温度和电解液的成分,可以控制这一过程。这些因素会影响electrodeposit的质量和特性,包括其厚度、附着力和均匀性。除了工业应用,electrodeposit过程在纳米技术领域也正在被探索。研究人员正在调查使用electrodeposit技术制造具有独特特性的纳米结构材料。这些材料在医学、能源储存和环境修复等多个领域具有潜在应用。例如,通过electrodeposit方法生产的纳米结构涂层可以通过增加表面积和改善电荷转移效率来提高电池和超级电容器的性能。总之,electrodeposit过程是一项重要技术,支撑着现代制造和材料科学的许多方面。其通过控制沉积增强材料特性的能力使其在从珠宝到电子产品等众多行业中都具有不可或缺的价值。随着研究的不断推进,electrodeposit技术的潜在应用可能会扩大,为应对当代挑战提供创新解决方案。理解和掌握electrodeposit的原理无疑将有助于未来技术的进步以及新材料的开发,以满足快速发展的世界的需求。