trioxid
简明释义
n. 三氧化物
英英释义
A chemical compound containing three oxygen atoms in its molecular structure. | 一种在其分子结构中含有三个氧原子的化合物。 |
单词用法
三氧化物化合物 | |
三氧化物形成 | |
三氧化物反应 | |
合成三氧化物 | |
分析三氧化物 | |
三氧化物稳定性 |
同义词
| 三氧化物 | Sulfur trioxide (SO3) is a key compound in the production of sulfuric acid. | 三氧化硫(SO3)是生产硫酸的关键化合物。 | |
| 氧化物 | The term 'oxide' can refer to various compounds containing oxygen. | ‘氧化物’一词可以指含有氧的各种化合物。 |
反义词
| 二氧化物 | 二氧化碳是一种常见的温室气体。 | ||
| 一氧化物 | 一氧化碳对人类是高度有毒的。 |
例句
1.High purity arsenic trioxid was obtained from the 2nd stage filtrate by reduction with SO2 flue gas, freeze crystallization, water dissolving, filtering and refining.
二段浸出后的滤液用二氧化硫烟道气还原,还原液经冷冻结晶、水溶、过滤、精制后可得纯度较高的精白砷。
2.High purity arsenic trioxid was obtained from the 2nd stage filtrate by reduction with SO2 flue gas, freeze crystallization, water dissolving, filtering and refining.
二段浸出后的滤液用二氧化硫烟道气还原,还原液经冷冻结晶、水溶、过滤、精制后可得纯度较高的精白砷。
3.The chemical compound known as trioxid is often used in industrial processes.
被称为三氧化物的化合物常用于工业过程。
4.The environmental impact of trioxid emissions is a growing concern among scientists.
科学家们对三氧化物排放的环境影响越来越关注。
5.Manufacturers are looking for ways to reduce trioxid waste during production.
制造商正在寻找减少生产过程中三氧化物废物的方法。
6.In the laboratory, we synthesized a new form of trioxid for our experiments.
在实验室中,我们合成了一种新的三氧化物用于我们的实验。
7.The presence of trioxid in the atmosphere can lead to serious health issues.
大气中存在的三氧化物可能导致严重的健康问题。
作文
In the realm of chemistry, the study of compounds and their interactions is crucial for understanding the material world around us. Among these compounds, those that contain oxygen are particularly interesting due to their varied applications and significance in both nature and industry. One such compound is known as trioxid, which refers to a chemical species that contains three oxygen atoms. The term trioxid comes from the Greek prefix 'tri-', meaning three, combined with 'oxide', which denotes the presence of oxygen. This composition allows trioxid compounds to exhibit unique properties that can be harnessed in various fields, including environmental science, materials engineering, and even medicine.For example, one of the most well-known trioxid compounds is sulfur trioxide (SO₃). This compound plays a significant role in the production of sulfuric acid, one of the most widely used industrial chemicals. Sulfuric acid is essential in battery production, fertilizer manufacturing, and petroleum refining. The ability of trioxid compounds like SO₃ to react with water to form strong acids illustrates the importance of understanding their chemical behavior.Beyond industrial applications, trioxid compounds also have implications for environmental chemistry. For instance, nitrogen trioxide (NO₃) is involved in atmospheric reactions that can lead to the formation of ozone in the troposphere, contributing to air quality issues. Understanding how trioxid compounds behave in the atmosphere helps scientists develop strategies to mitigate pollution and its effects on climate change.Moreover, the study of trioxid compounds extends into the field of biochemistry. Certain biological processes rely on the presence of oxygen in various forms, including trioxid species. For instance, reactive oxygen species (ROS), which can include forms of trioxid, are critical in cellular signaling and metabolism. However, an excess of these compounds can lead to oxidative stress, which is linked to numerous health issues such as cancer and neurodegenerative diseases. Thus, understanding the dual role of trioxid compounds in biological systems is essential for developing therapeutic approaches.In conclusion, the concept of trioxid compounds encompasses a wide range of substances with three oxygen atoms that play vital roles across various scientific disciplines. From industrial applications to environmental impact and biological significance, the study of trioxid compounds is integral to advancing our knowledge and addressing challenges in chemistry and beyond. As we continue to explore the complexities of these compounds, it becomes increasingly clear that mastering the understanding of trioxid will contribute to innovations that benefit society and the environment. Therefore, chemists and researchers must prioritize the investigation of trioxid compounds to unlock their full potential and harness their capabilities for future advancements.
在化学领域,化合物及其相互作用的研究对于理解我们周围的物质世界至关重要。在这些化合物中,含氧的化合物尤其有趣,因为它们在自然界和工业中的应用和重要性各不相同。其中一种化合物被称为trioxid,指的是含有三个氧原子的化学物种。术语trioxid源于希腊前缀'tri-',意为三,加上'oxide',表示氧的存在。这种组成使得trioxid化合物表现出独特的性质,可以在环境科学、材料工程甚至医学等多个领域中得到利用。例如,最著名的trioxid化合物之一是三氧化硫(SO₃)。该化合物在硫酸的生产中发挥着重要作用,硫酸是使用最广泛的工业化学品之一。硫酸在电池生产、肥料制造和石油精炼中至关重要。像SO₃这样的trioxid化合物与水反应形成强酸的能力,说明了理解其化学行为的重要性。除了工业应用,trioxid化合物在环境化学中也具有重要意义。例如,氮三氧化物(NO₃)参与大气反应,可能导致对流层臭氧的形成,从而影响空气质量。理解trioxid化合物在大气中的行为帮助科学家制定减轻污染及其对气候变化影响的策略。此外,trioxid化合物的研究还延伸到生物化学领域。某些生物过程依赖于以各种形式存在的氧,包括trioxid物种。例如,活性氧物种(ROS),其中可以包括trioxid的形式,在细胞信号传导和代谢中至关重要。然而,过量的这些化合物可能导致氧化应激,这与多种健康问题(如癌症和神经退行性疾病)有关。因此,理解trioxid化合物在生物系统中的双重角色对于开发治疗方法至关重要。总之,trioxid化合物的概念涵盖了多种含有三个氧原子的物质,这些物质在各个科学学科中发挥着重要作用。从工业应用到环境影响,再到生物学意义,trioxid化合物的研究对于推动我们知识的进步和解决化学及其他领域的挑战是不可或缺的。随着我们继续探索这些化合物的复杂性,越来越明显的是,掌握对trioxid的理解将有助于创新,造福社会和环境。因此,化学家和研究人员必须优先调查trioxid化合物,以解锁其全部潜力,并利用其能力推动未来的进步。
