electrolyzation

简明释义

英[ɪˌlektrəʊlaɪˈzeɪʃən]美[ɪˌlektrolɪˈzeʃən]

n. [化学] 电解

英英释义

单词用法

同义词

反义词

例句

1.The factors which effect the production of electrolyzation Ag are analysed, the production of electrolyzation Ag with the brand of IC-Ag 99.99 is steadily after adopting some measures.

对某厂影响银电解生产的因素进行了分析，在实践中采取措施，稳定了99.99牌号银的产出。

2.The factors which effect the production of electrolyzation Ag are analysed, the production of electrolyzation Ag with the brand of IC-Ag 99.99 is steadily after adopting some measures.

对某厂影响银电解生产的因素进行了分析，在实践中采取措施，稳定了99.99牌号银的产出。

3.The process of electrolyzation is crucial for separating hydrogen from water.

电解化的过程对于从水中分离氢气至关重要。

4.In the lab, we conducted an electrolyzation experiment to observe gas production.

在实验室，我们进行了一个电解化实验以观察气体产生。

5.The electrolyzation of saltwater can produce chlorine gas.

盐水的电解化可以产生氯气。

6.Understanding electrolyzation is essential for students studying chemistry.

理解电解化对学习化学的学生来说至关重要。

7.The electrolyzation process is used in various industrial applications.

在各种工业应用中都使用电解化过程。

作文

The process of electrolyzation is fundamental in various scientific and industrial applications. Essentially, electrolyzation refers to the chemical reaction that occurs when an electric current is passed through a liquid or solution that conducts electricity, known as an electrolyte. This process can lead to the decomposition of the electrolyte into its constituent elements or compounds. One of the most common examples of electrolyzation is the electrolysis of water, where water is split into hydrogen and oxygen gases. This reaction not only demonstrates the principles of chemistry but also has significant implications for energy production and storage. In recent years, the interest in electrolyzation has surged due to the growing demand for sustainable energy solutions. For instance, hydrogen produced through the electrolyzation of water is being explored as a clean fuel alternative. Unlike fossil fuels, hydrogen combustion produces only water as a byproduct, making it an environmentally friendly option. Moreover, the ability to generate hydrogen via renewable energy sources, such as solar or wind power, enhances its appeal as a sustainable energy carrier. The mechanism of electrolyzation involves two electrodes: an anode and a cathode, which are immersed in the electrolyte solution. When an electric current is applied, oxidation occurs at the anode while reduction takes place at the cathode. For example, during the electrolyzation of water, oxygen is released at the anode, and hydrogen is generated at the cathode. This separation of gases is crucial for various applications, including fuel cells and chemical synthesis. Furthermore, electrolyzation has important industrial applications beyond just hydrogen production. It is used in metal plating, where metals are deposited onto surfaces to enhance their properties, such as corrosion resistance and appearance. The process is also employed in the production of chlorine and sodium hydroxide, which are vital chemicals in numerous industries, including paper manufacturing and water treatment. Despite its advantages, electrolyzation also faces challenges, particularly regarding efficiency and cost. The energy required for the process can be substantial, and researchers are continually seeking ways to improve the efficiency of electrolyzation systems. Innovations in electrode materials and designs, as well as the integration of renewable energy sources, are key areas of focus in this field. In conclusion, electrolyzation is a pivotal process with wide-ranging implications for energy production, industrial applications, and environmental sustainability. As the world shifts towards cleaner energy solutions, understanding and optimizing electrolyzation will be essential in meeting future energy demands while minimizing our ecological footprint. The ongoing research and advancements in this area hold promise for a more sustainable and efficient energy landscape, making electrolyzation a critical topic in both scientific and industrial discussions today.

电解化过程在各种科学和工业应用中是基础性的。基本上，electrolyzation 指的是当电流通过一种导电的液体或溶液（称为电解质）时发生的化学反应。这个过程可以导致电解质分解成其组成元素或化合物。electrolyzation 最常见的例子之一是水的电解，其中水被分解成氢气和氧气。这一反应不仅展示了化学原理，还有重要的能量生产和储存的意义。 近年来，由于对可持续能源解决方案的日益需求，electrolyzation 的兴趣激增。例如，通过水的 electrolyzation 产生的氢气被探索作为一种清洁燃料替代品。与化石燃料不同，氢气燃烧只产生水作为副产品，使其成为一种环保的选择。此外，通过可再生能源（如太阳能或风能）产生氢气的能力增强了其作为可持续能源载体的吸引力。 electrolyzation 的机制涉及两个电极：阳极和阴极，它们浸没在电解质溶液中。当施加电流时，阳极发生氧化，而阴极发生还原。例如，在水的 electrolyzation 过程中，氧气在阳极释放，而氢气在阴极生成。气体的分离对于各种应用至关重要，包括燃料电池和化学合成。 此外，electrolyzation 在氢气生产之外还有重要的工业应用。它用于金属电镀，其中金属沉积在表面上，以增强其特性，如耐腐蚀性和外观。该过程还用于氯和氢氧化钠的生产，这些是许多行业（包括造纸和水处理）中重要的化学品。 尽管有其优势，electrolyzation 也面临挑战，特别是在效率和成本方面。该过程所需的能量可能相当大，研究人员正在不断寻求提高 electrolyzation 系统效率的方法。电极材料和设计的创新，以及可再生能源的整合，是该领域的关键关注点。 总之，electrolyzation 是一个具有广泛影响的关键过程，涉及能源生产、工业应用和环境可持续性。随着世界向更清洁的能源解决方案转型，理解和优化 electrolyzation 将对满足未来能源需求同时最小化我们的生态足迹至关重要。在这一领域的持续研究和进展为更可持续和高效的能源格局带来了希望，使 electrolyzation 成为当今科学和工业讨论中的一个关键话题。