azote

简明释义

英[əˈzoʊt]美[əˈzoʊt]

n. 氮（nitrogen 的旧称）

英英释义

单词用法

同义词

反义词

例句

1.4 , screw thread gob produced by internation standard , material is 38chrome molybdenum aluminium azote steel , high rigidity , long time.

四螺纹口按国际标准化制造，材料选用38铬钼铝氮化钢，硬度高，使用寿命长。

2.4 , screw thread gob produced by internation standard , material is 38chrome molybdenum aluminium azote steel , high rigidity , long time.

四螺纹口按国际标准化制造，材料选用38铬钼铝氮化钢，硬度高，使用寿命长。

3.Said doping gas control part includes a gas quality flowmeter (of argon and azote) used by a gas protect part, and a doping case part.

所述的掺杂气体控制部分包气体保护部分使用的氩气、氮气的气体质量流量计及掺杂箱部分；

4.Content of azote and kalium in the soil of normal field is 34.7% and 13.9% less than in red leaf field.

土样检测发现正常棉叶田所采土样中全氮、全钾含量比红叶田土样减少34.7%和13.9%。

5.The wetting property of PET fiber was ameliorated obviously by the azote plasma treatment.

用氮气对涤纶进行低温等离子处理，明显地改善了其表面的润湿性能。

6.The farmer used azote to enrich the soil for better crop yields.

农民使用azote来丰富土壤，以提高作物产量。

7.In chemistry class, we learned that azote is essential for plant growth.

在化学课上，我们了解到azote对植物生长至关重要。

8.The scientist explained how azote contributes to the nitrogen cycle.

科学家解释了azote如何促进氮循环。

9.Adding azote to the compost helped accelerate decomposition.

将azote添加到堆肥中有助于加速分解。

10.Farmers often test their soil for azote levels before planting.

农民在种植前经常测试土壤中的azote水平。

作文

In the realm of chemistry and biology, the term azote refers to nitrogen, which is an essential element for life on Earth. It plays a crucial role in the formation of amino acids, proteins, and nucleic acids. Nitrogen makes up about 78% of the Earth's atmosphere, yet it is often overlooked in discussions about essential nutrients. This oversight is surprising considering that without azote (氮), life as we know it would not exist. The significance of azote can be observed in various biological processes, particularly in the nitrogen cycle, where it is converted into different forms that can be utilized by living organisms. The nitrogen cycle begins with nitrogen fixation, a process carried out by certain bacteria that convert atmospheric azote (氮) into ammonia, a form that plants can absorb. These plants are then consumed by animals, which utilize the proteins derived from them. When animals excrete waste or die, decomposers break down these organic materials, releasing nitrogen back into the soil in a form that can again be used by plants. This cyclical process highlights the importance of azote in maintaining the balance of ecosystems. Moreover, azote is a key component of fertilizers, which are used extensively in agriculture to enhance crop yields. Farmers apply nitrogen-rich fertilizers to ensure that their crops receive adequate nutrients for growth. However, the overuse of these fertilizers can lead to environmental issues such as water pollution and eutrophication, where excess nitrogen runs off into water bodies, causing algal blooms that deplete oxygen levels and harm aquatic life. This illustrates the delicate balance that must be maintained when managing azote (氮) in agricultural practices. In addition to its biological significance, azote has industrial applications as well. It is used in the production of nitric acid, which is a precursor for many chemicals, including explosives and fertilizers. The Haber-Bosch process, which synthesizes ammonia from atmospheric azote (氮) and hydrogen, revolutionized agriculture and industry in the early 20th century. This process enabled the mass production of fertilizers, which significantly increased food production and helped sustain the growing global population. Despite its importance, the concept of azote is often misunderstood. Many people associate nitrogen primarily with pollution or as a harmful gas, neglecting its vital role in supporting life. Educating the public about the benefits and functions of azote (氮) can foster a greater appreciation for this element and encourage more sustainable practices in its use. In conclusion, azote is an indispensable component of life on Earth, integral to both biological processes and industrial applications. Understanding its role in the nitrogen cycle, its importance in agriculture, and its various uses can help us appreciate the complexity of ecosystems and the necessity of responsible management of this essential element. As we continue to face challenges related to food security and environmental sustainability, recognizing the value of azote (氮) will be crucial in finding solutions that benefit both humanity and the planet.

在化学和生物学的领域中，术语azote指的是氮，这是一种对地球生命至关重要的元素。它在氨基酸、蛋白质和核酸的形成中发挥着关键作用。氮占据了地球大气的约78%，然而在关于必需营养素的讨论中，它常常被忽视。这种忽视令人惊讶，因为没有azote（氮），我们所知的生命将无法存在。azote的重要性可以在各种生物过程中观察到，特别是在氮循环中，在这个过程中，氮被转化为不同的形式，以供生物体利用。 氮循环始于氮固定，这是由某些细菌进行的一个过程，这些细菌将大气中的azote（氮）转化为氨，植物可以吸收这种形式。然后这些植物被动物消费，动物利用从中获得的蛋白质。当动物排泄废物或死亡时，分解者会分解这些有机材料，将氮以一种可以再次被植物使用的形式释放回土壤。这一循环过程突显了azote在维持生态系统平衡中的重要性。 此外，azote是肥料的关键成分，这些肥料在农业中被广泛使用，以提高作物产量。农民施用富含氮的肥料，以确保他们的作物获得足够的营养以促进生长。然而，过度使用这些肥料可能导致环境问题，如水污染和富营养化，过量的氮流入水体，导致藻类繁殖，消耗氧气并危害水生生命。这说明在农业实践中管理azote（氮）的微妙平衡。 除了其生物学意义外，azote还具有工业应用。它用于生产硝酸，硝酸是许多化学品的前体，包括炸药和肥料。哈伯-博施法则通过将大气中的azote（氮）与氢合成氨，彻底改变了20世纪早期的农业和工业。这个过程使得肥料的大规模生产成为可能，显著提高了粮食生产，帮助维持不断增长的全球人口。 尽管其重要性，azote的概念常常被误解。许多人主要将氮与污染或有害气体联系在一起，忽视了它在支持生命中的重要作用。教育公众了解azote（氮）的好处和功能，可以培养对这一元素的更大欣赏，并鼓励更可持续的使用实践。 总之，azote是地球生命不可或缺的组成部分，对生物过程和工业应用都至关重要。理解它在氮循环中的作用、在农业中的重要性以及它的各种用途，可以帮助我们欣赏生态系统的复杂性以及负责任地管理这一基本元素的必要性。随着我们继续面临与粮食安全和环境可持续性相关的挑战，认识到azote（氮）的价值将在寻找有利于人类和地球的解决方案中至关重要。