tetroxide

简明释义

英[teˈtrɒksɪd]美[teˈtrɑːkˌsaɪd]

n. [无化] 四氧化物

英英释义

单词用法

同义词

反义词

例句

1.This study is significant for enhancing the quality control of the nitrogen tetroxide on launch site.

该课题的研究对于提高发射场四氧化二氮质量控制水平具有十分重要的意义。

2.The influencing factors of uncertainty of measurement for determination of equivalent water content in nitrogen tetroxide by NMR method we established were discussed in this paper.

讨论了自行建立的核磁共振法测定四氧化二氮中相当水含量测量不确定度的影响因素，并对各不确定度分量和测量结果的不确定度进行了评定。

3.Methods: Ruthenium tetroxide and osmium tetroxide were compared as post fixative in the preparation of hairless epidermis for transmission electron microscopic examination.

方法：裸鼠表皮分别用四氧化钌和锇酸固定后电镜下观察裸鼠表皮角质层脂质的超微结构。

4.The methods of preparing and measuring of trimanganese tetroxide are introduced in the paper.

介绍了四氧化三锰的制备、检测方法及其相关理论研究。

5.The influencing factors of uncertainty of measurement for determination of equivalent water content in nitrogen tetroxide by NMR method we established were discussed in this paper.

讨论了自行建立的核磁共振法测定四氧化二氮中相当水含量测量不确定度的影响因素，并对各不确定度分量和测量结果的不确定度进行了评定。

6.The oxygen utilization rate is low in manganese tetroxide preparation by metallic manganese powder suspending liquid process.

在金属锰粉悬浮液法制备四氧化三锰过程中存在氧气利用率较低的情况。

7.During the experiment, we measured the concentration of tetroxide in the solution.

在实验过程中，我们测量了溶液中四氧化物的浓度。

8.The chemical compound known as tetroxide is crucial in the production of certain types of rocket fuel.

被称为四氧化物的化合物在某些类型火箭燃料的生产中至关重要。

9.In laboratories, tetroxide is often used as a reagent for various chemical reactions.

在实验室中，四氧化物通常用作各种化学反应的试剂。

10.The formation of tetroxide can occur during the oxidation of certain organic compounds.

在某些有机化合物的氧化过程中，可能会形成四氧化物。

11.Safety equipment is essential when handling tetroxide due to its toxic properties.

由于其毒性特性，处理四氧化物时必须使用安全设备。

作文

Tetroxide is a term that refers to a chemical compound containing four oxygen atoms in its molecular structure. One of the most well-known examples of a tetroxide is dinitrogen tetroxide (N2O4), which is used primarily as an oxidizer in rocket propellants. Understanding the significance of this compound requires a basic knowledge of chemistry and its applications. In this essay, we will explore the properties, uses, and implications of tetroxides in various fields, particularly in aerospace engineering and environmental science.The structure of a tetroxide can be visualized as a molecule where four oxygen atoms are bonded together with other elements. This unique arrangement gives tetroxides distinct properties, such as high reactivity and the ability to act as strong oxidizing agents. For instance, dinitrogen tetroxide can easily convert to nitrogen dioxide (NO2) under certain conditions, which is a critical reaction in combustion processes. The ability of tetroxides to facilitate combustion makes them invaluable in the aerospace industry, where they are often utilized in rocket fuels. The controlled reaction of tetroxides with fuel can produce the necessary thrust to propel spacecraft into orbit.Moreover, the role of tetroxides extends beyond aerospace applications. In environmental science, understanding how tetroxides interact with other compounds can help in assessing air quality and pollution control. For example, the presence of nitrogen tetroxide in the atmosphere can contribute to the formation of smog and other air pollutants. Therefore, studying tetroxides not only aids in technological advancements but also plays a crucial role in environmental protection efforts.Despite their usefulness, tetroxides must be handled with care due to their reactive nature. Safety protocols are essential when working with these compounds, especially in laboratory settings. Researchers and engineers must be aware of the potential hazards associated with tetroxides, including toxicity and the risk of explosion when improperly managed. Consequently, proper training and safety measures are paramount in any situation involving tetroxide.In conclusion, the term tetroxide represents a class of chemical compounds that are vital in multiple domains, including aerospace engineering and environmental science. Their unique properties make them powerful tools for innovation, yet they also pose significant safety challenges. As we continue to explore the potential of tetroxides, it is imperative to balance their applications with responsible handling practices. Through ongoing research and development, we can harness the benefits of tetroxide compounds while minimizing their risks to human health and the environment.

四氧化物是指分子结构中含有四个氧原子的化合物。最著名的四氧化物之一是二氮四氧化物（N2O4），主要用作火箭推进剂中的氧化剂。理解这种化合物的重要性需要对化学及其应用有基本的了解。在这篇文章中，我们将探讨四氧化物的性质、用途以及在各个领域，特别是在航空航天工程和环境科学中的影响。四氧化物的结构可以想象为一个分子，其中四个氧原子与其他元素结合在一起。这种独特的排列使四氧化物具有明显的特性，例如高反应性和作为强氧化剂的能力。例如，二氮四氧化物在某些条件下可以轻易转化为二氧化氮（NO2），这是燃烧过程中的关键反应。四氧化物促进燃烧的能力使其在航空航天工业中变得不可或缺，常用于火箭燃料中。四氧化物与燃料的受控反应可以产生必要的推力，将航天器发射到轨道上。此外，四氧化物的作用不仅限于航空航天应用。在环境科学中，了解四氧化物与其他化合物的相互作用有助于评估空气质量和污染控制。例如，氮四氧化物在大气中的存在可能会导致烟雾和其他空气污染物的形成。因此，研究四氧化物不仅有助于技术进步，也在环境保护工作中发挥着至关重要的作用。尽管四氧化物很有用，但由于其反应性，必须小心处理。在实验室环境中，处理这些化合物时必须遵循安全协议。研究人员和工程师必须意识到与四氧化物相关的潜在危害，包括毒性和在管理不当时引发爆炸的风险。因此，在任何涉及四氧化物的情况下，适当的培训和安全措施是至关重要的。总之，术语四氧化物代表了一类在多个领域（包括航空航天工程和环境科学）中至关重要的化学化合物。它们独特的性质使其成为创新的强大工具，但同时也带来了显著的安全挑战。随着我们继续探索四氧化物的潜力，平衡其应用与负责任的处理实践至关重要。通过持续的研究和开发，我们可以利用四氧化物化合物的好处，同时将其对人类健康和环境的风险降到最低。