oxidic
简明释义
[化学] 氧化的
英英释义
Relating to or containing oxygen, especially in a chemical compound. | 与氧气有关或含有氧气,特别是在化合物中。 |
单词用法
氧化层 | |
氧化矿物 | |
氧化半导体 | |
氧化催化剂 |
同义词
| 氧化的 | 氧化压力可能导致细胞损伤。 | ||
| 可氧化的 | 在特定条件下,某些金属是可氧化的。 |
反义词
| 还原的 | 还原过程在有机化学中是必不可少的。 | ||
| 非氧化的 | Non-oxidizing conditions are required for certain reactions. | 某些反应需要非氧化条件。 |
例句
1.The study of the application of permeated-filtered technique to the oxidic copper ore acidized technics is reported in the article.
本文介绍了氧化铜矿酸溶工艺中渗滤溶解技术的应用研究。
2.The stability and composition of oxidic film and the C-V characteristics of MOS structure have also been tested and analysed theoretically in this paper.
对氧化膜的组分和稳定性,以及MOS结构的C—V特性进行了实际测量和理论分析。
3.A new kind of silicon oxidic film on aluminum was prepared by chemical vapor deposition (CVD) in ambient pressure.
本研究采用常压化学气相沉积(CVD)的方法在金属铝基底上制备出硅氧化合物陶瓷膜层。
4.The stability and composition of oxidic film and the C-V characteristics of MOS structure have also been tested and analysed theoretically in this paper.
对氧化膜的组分和稳定性,以及MOS结构的C—V特性进行了实际测量和理论分析。
5.At the same time, stress and active anion will destroy the oxidic film.
与此同时,应力和活性阴离子对氧化膜的破坏造成孔蚀;
6.The researcher discovered an oxidic 氧化的 compound that enhanced the catalytic process.
研究人员发现了一种增强催化过程的氧化的化合物。
7.In metallurgy, oxidic 氧化的 layers can affect the properties of metals.
在冶金学中,氧化的层会影响金属的性质。
8.The oxidic 氧化的 materials were used in the production of semiconductors.
这些氧化的材料被用于半导体的生产。
9.The presence of oxidic 氧化的 impurities can significantly alter the performance of a catalyst.
存在的氧化的杂质可以显著改变催化剂的性能。
10.We analyzed the oxidic 氧化的 films for their electrical conductivity.
我们分析了这些氧化的薄膜的电导率。
作文
The term oxidic refers to a class of compounds that contain oxygen in the form of oxides. These compounds play a crucial role in various fields, including chemistry, materials science, and environmental studies. Understanding oxidic substances is essential for anyone interested in these disciplines, as they are fundamental to many chemical reactions and processes.In chemistry, oxidic compounds are often formed when elements react with oxygen. For instance, when metals such as iron or copper are exposed to oxygen, they can form oxides like iron oxide (rust) or copper oxide. These reactions are not only significant in industrial applications but also in everyday life; for example, the rusting of metal objects is a common phenomenon that involves oxidic reactions.Furthermore, oxidic materials are critical in the development of catalysts, which are substances that increase the rate of chemical reactions without being consumed in the process. Many catalysts used in industrial processes are based on oxidic structures, which help to facilitate reactions by providing a surface for reactants to interact. This is particularly important in the production of chemicals, fuels, and pharmaceuticals, where efficiency and speed are paramount.In the realm of materials science, oxidic compounds are often studied for their electrical and thermal properties. For example, certain oxidic materials, such as titanium dioxide, are used in the production of semiconductors and photovoltaic cells. These materials exhibit unique characteristics that make them suitable for applications in electronics and renewable energy technologies. As the world shifts towards more sustainable energy solutions, understanding the properties and applications of oxidic materials becomes increasingly important.Moreover, oxidic compounds have significant implications for environmental science. The formation of oxides in the atmosphere can lead to various environmental issues, including air pollution and climate change. For instance, nitrogen oxides (NOx) and sulfur oxides (SOx) are notorious pollutants that contribute to smog formation and acid rain. By studying oxidic compounds and their interactions in the environment, scientists can develop strategies to mitigate their negative impacts and promote cleaner air quality.In summary, the concept of oxidic compounds encompasses a wide range of applications and implications across multiple scientific fields. From their role in chemical reactions to their importance in materials science and environmental studies, oxidic substances are integral to our understanding of both natural and synthetic processes. As we continue to explore the complexities of these compounds, we gain valuable insights that can lead to advancements in technology, sustainability, and our overall quality of life. Therefore, a thorough comprehension of oxidic materials is essential for students, researchers, and professionals alike, highlighting the interconnectedness of science and its impact on our world.
术语oxidic指的是一类含有氧的化合物,这些化合物以氧化物的形式存在。这些化合物在化学、材料科学和环境研究等多个领域中发挥着至关重要的作用。理解oxidic物质对任何对这些学科感兴趣的人来说都是必不可少的,因为它们是许多化学反应和过程的基础。在化学中,oxidic化合物通常是在元素与氧反应时形成的。例如,当铁或铜等金属暴露在氧气中时,它们可以形成氧化铁(锈)或氧化铜等氧化物。这些反应不仅在工业应用中具有重要意义,而且在日常生活中也是如此;例如,金属物体的生锈就是一个涉及oxidic反应的常见现象。此外,oxidic材料在催化剂的发展中至关重要,催化剂是指能够提高化学反应速率而不被消耗的物质。许多用于工业过程的催化剂是基于oxidic结构的,这有助于通过提供反应物相互作用的表面来促进反应。这在化学品、燃料和药物的生产中尤为重要,因为效率和速度至关重要。在材料科学领域,oxidic化合物因其电气和热性能而受到研究。例如,某些oxidic材料,如二氧化钛,被用于半导体和光伏电池的生产。这些材料展现出独特的特性,使其适合用于电子和可再生能源技术的应用。随着世界向更可持续的能源解决方案转变,理解oxidic材料的特性和应用变得越来越重要。此外,oxidic化合物对环境科学也有重大影响。大气中的氧化物形成可能导致各种环境问题,包括空气污染和气候变化。例如,氮氧化物(NOx)和硫氧化物(SOx)是臭名昭著的污染物,会导致雾霾形成和酸雨。通过研究oxidic化合物及其在环境中的相互作用,科学家可以制定减轻其负面影响和促进清洁空气质量的策略。总之,oxidic化合物的概念涵盖了多个科学领域的广泛应用和影响。从它们在化学反应中的作用到在材料科学和环境研究中的重要性,oxidic物质对我们理解自然和合成过程至关重要。随着我们继续探索这些化合物的复杂性,我们获得的宝贵见解可以推动技术、可持续性和我们整体生活质量的进步。因此,全面理解oxidic材料对于学生、研究人员和专业人士来说都是必不可少的,突显了科学的相互联系及其对我们世界的影响。
