oxid

简明释义

英[ˈɒksɪd]美[ˈɒksɪd]

n. 氧化物

英英释义

单词用法

同义词

反义词

例句

1.The reaction equation in a complex oxid - reduction, according to the authors, can be balanced by combining oxidization algorithm with coefficient algebra, which gives more than one correct answer.

氧化数法结合系数代数法可以求出复杂体系氧化还原反应配平式，但正确答案往往不是唯一的。

2.The reaction equation in a complex oxid - reduction, according to the authors, can be balanced by combining oxidization algorithm with coefficient algebra, which gives more than one correct answer.

氧化数法结合系数代数法可以求出复杂体系氧化还原反应配平式，但正确答案往往不是唯一的。

3.The ore is lead mine of partial oxidation, the lead ore consists chiefly of galena and cerusite. 39% of cerusite is the most oxid in lead ore.

所处理矿石为半氧化铅矿石，矿石中铅以方铅矿和白铅矿形式产出，铅的氧化物主要为白铅矿，分布率达39%。

4.The method and skill for balancing a complex oxid - reduction reaction equation are discussed in this paper.

本文介绍复杂氧化还原反应式配平的方法和技巧。

5.The process of rusting involves the formation of iron oxide.

生锈的过程涉及铁的氧化物形成。

6.The oxidation of glucose is essential for cellular respiration.

葡萄糖的氧化对于细胞呼吸至关重要。

7.Copper oxide is often used in the production of electrical components.

铜的氧化物常用于电气元件的生产。

8.When metals react with oxygen, they form oxides that can affect their properties.

当金属与氧气反应时，会形成影响其性质的氧化物。

9.The oxidation state of an element helps predict its chemical behavior.

元素的氧化态有助于预测其化学行为。

作文

The term oxid is often associated with the process of oxidation, which is a fundamental concept in chemistry. Oxidation involves the loss of electrons from an atom or molecule, leading to a change in its chemical state. This process is not only important in laboratory settings but also plays a crucial role in various natural phenomena. For instance, when iron reacts with oxygen in the presence of moisture, it forms rust, a common example of oxidation. In this case, iron is the substance that undergoes oxidation, losing electrons and resulting in the formation of iron oxides. Understanding the implications of oxid reactions can help us better comprehend the world around us, from the rusting of metals to the metabolic processes in living organisms. In biological systems, oxidation is essential for energy production. Cells utilize oxygen to convert glucose into energy through a series of reactions known as cellular respiration. During this process, glucose is oxidized, and energy is released in the form of ATP (adenosine triphosphate). The significance of oxid reactions in metabolism cannot be overstated, as they are vital for sustaining life. Without the ability to oxidize nutrients, organisms would be unable to generate the energy required for growth, reproduction, and maintenance of cellular functions. Moreover, the concept of oxid extends beyond simple chemical reactions; it also encompasses various applications in technology and industry. For example, the field of materials science often investigates the oxidation of metals to enhance their properties. By understanding how different materials react with oxygen, scientists can develop coatings and treatments that prevent corrosion, thereby extending the lifespan of structures and components. This application of oxid knowledge is particularly relevant in industries such as construction, automotive, and aerospace, where material integrity is paramount. Furthermore, the study of oxid processes has implications for environmental science as well. The oxidation of pollutants in the atmosphere can lead to the formation of smog and acid rain, both of which have detrimental effects on ecosystems and human health. By monitoring and controlling oxid reactions, environmental scientists aim to mitigate these adverse impacts and promote sustainability. For instance, strategies like catalytic converters in vehicles are designed to facilitate the oxidation of harmful emissions, transforming them into less harmful substances before they are released into the atmosphere. In conclusion, the word oxid encapsulates a wide range of concepts across various fields, from chemistry and biology to materials science and environmental studies. Its relevance in everyday life is profound, affecting everything from the food we eat to the air we breathe. By deepening our understanding of oxid processes, we can unlock new solutions to some of the most pressing challenges faced by society today. Whether it’s improving energy efficiency, protecting our environment, or advancing technological innovations, the study of oxid remains a cornerstone of scientific inquiry and practical application.

术语oxid通常与氧化过程相关，这是化学中的一个基本概念。氧化涉及从原子或分子中失去电子，导致其化学状态的变化。这个过程不仅在实验室环境中重要，而且在各种自然现象中也发挥着至关重要的作用。例如，当铁在潮湿条件下与氧气反应时，它会形成锈，这是一种氧化的常见例子。在这种情况下，铁是经历氧化的物质，失去电子，从而形成铁氧化物。理解oxid反应的影响可以帮助我们更好地理解周围的世界，从金属生锈到生物体内的代谢过程。 在生物系统中，氧化对能量生产至关重要。细胞利用氧气通过一系列称为细胞呼吸的反应将葡萄糖转化为能量。在此过程中，葡萄糖被氧化，能量以ATP（腺苷三磷酸）的形式释放。oxid反应在代谢中的重要性不容忽视，因为它们对维持生命至关重要。如果没有氧化营养物质的能力，生物体将无法产生生长、繁殖和维持细胞功能所需的能量。 此外，oxid的概念超越了简单的化学反应；它还涵盖了技术和工业中的各种应用。例如，材料科学领域经常研究金属的氧化以增强其性能。通过了解不同材料与氧气的反应，科学家可以开发防腐涂层和处理方法，从而延长结构和组件的使用寿命。这种oxid知识的应用在建筑、汽车和航空航天等行业中尤其相关，其中材料完整性至关重要。 此外，oxid过程的研究对环境科学也有影响。大气中污染物的氧化可能导致烟雾和酸雨的形成，这两者对生态系统和人类健康都有害。通过监测和控制oxid反应，环境科学家旨在减轻这些不利影响并促进可持续发展。例如，车辆中的催化转换器旨在促进有害排放的氧化，将其转化为释放到大气中之前的无害物质。 总之，单词oxid涵盖了各个领域的广泛概念，从化学和生物学到材料科学和环境研究。它在日常生活中的相关性深远，影响着我们所吃的食物和我们呼吸的空气。通过加深对oxid过程的理解，我们可以为解决当今社会面临的一些最紧迫的挑战解锁新的解决方案。无论是提高能源效率、保护我们的环境，还是推动技术创新，oxid的研究仍然是科学探究和实际应用的基石。