electrolytics

简明释义

英[ˌɛlɛkˈtrɒlɪtɪks]美[ˌɛlɛkˈtrɑːlɪtɪks]

n. 电解学；电解化学

英英释义

单词用法

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反义词

例句

1.The process of separating metals from ores often involves the use of electrolytics 电解质 to facilitate the extraction.

分离金属与矿石的过程通常涉及使用electrolytics电解质来促进提取。

2.In batteries, electrolytics 电解质 play a crucial role in allowing the flow of electrical current.

在电池中，electrolytics电解质在允许电流流动方面起着关键作用。

3.Researchers are developing new electrolytics 电解质 that can operate at higher temperatures for better efficiency.

研究人员正在开发新的electrolytics电解质，以便在更高温度下运行以提高效率。

4.The quality of electrolytics 电解质 used in electroplating determines the finish of the coated surface.

用于电镀的electrolytics电解质的质量决定了涂层表面的光洁度。

5.During the experiment, we measured the conductivity of various electrolytics 电解质 solutions.

在实验过程中，我们测量了各种electrolytics电解质溶液的导电性。

作文

The field of chemistry offers a vast array of fascinating concepts, one of which is the study of electrolytics (电解质). This term refers to substances that dissociate into ions when dissolved in a solvent, typically water, and are crucial for various chemical reactions. Understanding electrolytics is essential not only for chemists but also for anyone interested in the natural sciences, as they play a pivotal role in both biological systems and industrial applications. To grasp the importance of electrolytics, we must first explore their function in living organisms. The human body relies on a delicate balance of electrolytics to maintain physiological processes. For instance, sodium, potassium, and calcium are vital electrolytics that help regulate nerve function, muscle contraction, and hydration levels. An imbalance of these ions can lead to severe health issues, such as dehydration or cardiac arrest, highlighting the necessity of maintaining proper electrolyte levels. In addition to their biological significance, electrolytics are also integral to numerous industrial processes. In the manufacturing of batteries, for example, electrolytics facilitate the movement of ions between the anode and cathode, allowing for the storage and release of electrical energy. This principle is not only applicable to batteries but also to electroplating, where electrolytics are used to deposit a layer of metal onto a surface, enhancing its appearance and resistance to corrosion. Moreover, the study of electrolytics extends to environmental science. Water quality testing often involves measuring the concentration of various electrolytics to determine the health of aquatic ecosystems. High levels of certain electrolytics, such as nitrates and phosphates, can indicate pollution and lead to harmful algal blooms, which disrupt marine life and water quality. Understanding the behavior of electrolytics in solution is fundamental to predicting their interactions and effects. The concept of conductivity is closely related to electrolytics, as solutions containing these ions can conduct electricity. This property is exploited in various applications, from medical diagnostics to the development of sensors that monitor environmental conditions. Furthermore, the advancements in technology have led to innovative uses of electrolytics. In recent years, researchers have been exploring the potential of using ionic liquids—salts in liquid form that exhibit unique electrolytics properties—for applications in green chemistry and sustainable energy. These liquids have lower volatility and can be tailored for specific reactions, making them an exciting area of research for the future. In conclusion, the study of electrolytics (电解质) is a multifaceted topic that intersects with various scientific disciplines. From their critical role in biological systems to their applications in industry and environmental science, electrolytics are indispensable to our understanding of both natural and artificial processes. As we continue to explore and innovate, the knowledge of electrolytics will undoubtedly remain a cornerstone of scientific inquiry and technological advancement.

化学领域提供了众多迷人的概念，其中之一就是对electrolytics（电解质）的研究。这个术语指的是在溶剂中（通常是水）溶解时会离解成离子的物质，对于各种化学反应至关重要。理解electrolytics不仅对化学家至关重要，对任何对自然科学感兴趣的人来说也是如此，因为它们在生物系统和工业应用中发挥着关键作用。 为了理解electrolytics的重要性，我们首先必须探讨它们在生物体中的功能。人体依赖于electrolytics的微妙平衡来维持生理过程。例如，钠、钾和钙是维持神经功能、肌肉收缩和水合水平所必需的重要electrolytics。这些离子的失衡可能导致严重的健康问题，如脱水或心脏骤停，突显了保持适当电解质水平的必要性。 除了生物学意义外，electrolytics在许多工业过程中也不可或缺。例如，在电池制造中，electrolytics促进离子在阳极和阴极之间的移动，从而允许储存和释放电能。这一原理不仅适用于电池，还适用于电镀，其中使用electrolytics在表面上沉积金属层，以增强其外观和耐腐蚀性。 此外，electrolytics的研究还扩展到环境科学。水质检测通常涉及测量各种electrolytics的浓度，以确定水生生态系统的健康状况。某些electrolytics（如硝酸盐和磷酸盐）的高水平可能表明污染，并导致有害的藻类繁殖，从而破坏海洋生物和水质。 理解electrolytics在溶液中的行为对于预测它们的相互作用和影响至关重要。导电性的概念与electrolytics密切相关，因为含有这些离子的溶液可以导电。这一特性被广泛应用于各种应用中，从医学诊断到开发监测环境条件的传感器。 此外，科技的进步使得electrolytics的创新用途不断涌现。近年来，研究人员一直在探索使用离子液体——以液态形式存在的盐，具有独特的electrolytics特性——在绿色化学和可持续能源中的潜在应用。这些液体挥发性较低，可以针对特定反应进行定制，成为未来研究的一个令人兴奋的领域。 总之，electrolytics（电解质）的研究是一个多方面的话题，涉及多个科学学科。从它们在生物系统中的关键作用到它们在工业和环境科学中的应用，electrolytics对我们理解自然和人工过程至关重要。随着我们继续探索和创新，对electrolytics的知识无疑将仍然是科学研究和技术进步的基石。