ammonify

简明释义

[əˈmɒnɪˌfaɪ][əˈmɑːnɪfaɪ]

v. 使……氨化;加氨,加氨于……

第 三 人 称 单 数 a m m o n i f i e s

现 在 分 词 a m m o n i f y i n g

过 去 式 a m m o n i f i e d

过 去 分 词 a m m o n i f i e d

英英释义

To convert a substance into ammonia or to treat it with ammonia.

将某种物质转化为氨或用氨处理它。

单词用法

ammonify organic matter

氨化有机物

ammonifying agents

氨化剂

ammonify through decomposition

通过分解氨化

ammonify with nitrogen sources

用氮源进行氨化

同义词

ammoniate

氨化

The process of ammoniation is essential in the production of fertilizers.

氨化过程在肥料生产中至关重要。

nitrify

硝化

Nitrification is a key step in the nitrogen cycle, converting ammonia into nitrates.

硝化是氮循环中的关键步骤,将氨转化为硝酸盐。

fertilize

施肥

Farmers often fertilize their crops with ammonium-based fertilizers.

农民常用基于铵的肥料给作物施肥。

反义词

decompose

分解

The organic matter will decompose over time.

有机物质会随着时间的推移而分解。

dissolve

溶解

Salt can dissolve in water easily.

盐可以很容易地溶解在水中。

例句

1.The process of ammonifying the soil can improve crop yields significantly.

土壤的氨化过程可以显著提高作物产量。

2.To ammonify the compost, we added a nitrogen source to accelerate decomposition.

为了氨化堆肥,我们添加了氮源以加速分解。

3.Researchers are studying how to effectively ammonify agricultural residues.

研究人员正在研究如何有效地氨化农业残留物。

4.In organic chemistry, we often need to ammonify substances to create nitrogen-rich fertilizers.

在有机化学中,我们经常需要氨化物质以制造富含氮的肥料。

5.Farmers use various methods to ammonify organic waste for better soil health.

农民使用各种方法来氨化有机废物,以改善土壤健康。

作文

In the world of chemistry and biology, understanding the processes that occur within living organisms is crucial. One such process is the transformation of organic matter into simpler compounds, which can be vital for nutrient cycling in ecosystems. A fascinating aspect of this transformation is the process known as ammonify, or in Chinese, 氨化. This process involves the conversion of nitrogen-containing compounds into ammonia, which is an essential nutrient for many organisms.When organic matter decomposes, microorganisms play a significant role in breaking down complex molecules. During this decomposition, proteins and nucleic acids, which are rich in nitrogen, are broken down into simpler substances. The initial step in this breakdown is often the process of ammonify, where these nitrogen-rich compounds are converted into ammonia. This process is not only important for the recycling of nutrients but also for maintaining the nitrogen balance in the environment.The significance of ammonify extends beyond just nutrient cycling. In agricultural practices, understanding how to enhance this process can lead to improved soil fertility. Farmers often aim to optimize conditions that promote ammonify, ensuring that nitrogen is readily available for plants. This is particularly important because nitrogen is one of the key elements that plants need for growth. By enhancing the process of ammonify, farmers can increase crop yields and contribute to food security.Moreover, the process of ammonify has implications for environmental management. In natural ecosystems, the accumulation of organic matter can lead to an imbalance in nutrient levels if not properly managed. By promoting the activity of microorganisms that facilitate ammonify, ecosystems can maintain healthier nitrogen levels, reducing the risk of problems such as eutrophication in aquatic systems.In addition to its ecological importance, ammonify also has applications in waste management. In wastewater treatment facilities, the process of converting organic waste into ammonia through ammonify is crucial for managing nitrogen levels in effluents. This helps prevent the release of excess nitrogen into water bodies, which can cause harmful algal blooms and degrade water quality.In conclusion, the process of ammonify plays a vital role in various biological and ecological processes. From enhancing soil fertility in agriculture to maintaining balanced ecosystems and managing waste, understanding and harnessing ammonify can have significant benefits. As we continue to explore the intricacies of life and its chemical foundations, the importance of processes like ammonify will undoubtedly remain at the forefront of scientific inquiry and practical application.

在化学和生物学的世界中,理解生物体内发生的过程至关重要。一个这样的过程是有机物转化为简单化合物,这对生态系统中的养分循环至关重要。这个转化的一个迷人方面是被称为氨化的过程,这涉及将含氮化合物转化为氨,而氨是许多生物所需的重要营养素。当有机物分解时,微生物在分解复杂分子方面发挥着重要作用。在这种分解过程中,富含氮的蛋白质和核酸被分解为更简单的物质。这个分解的初始步骤通常是氨化过程,在这个过程中,这些富含氮的化合物被转化为氨。这个过程不仅对养分的循环至关重要,而且对维持环境中的氮平衡也至关重要。氨化的重要性超出了养分循环的范畴。在农业实践中,了解如何增强这一过程可以提高土壤肥力。农民们常常旨在优化促进氨化的条件,以确保氮对植物是 readily available 的。这一点尤其重要,因为氮是植物生长所需的关键元素之一。通过增强氨化过程,农民可以增加作物产量,并有助于粮食安全。此外,氨化过程对环境管理也有影响。在自然生态系统中,若不妥善管理,有机物的积累可能导致养分水平失衡。通过促进促进氨化的微生物的活动,生态系统可以维持更健康的氮水平,减少如水体富营养化等问题的风险。除了其生态重要性外,氨化在废物管理中也有应用。在废水处理设施中,通过氨化将有机废物转化为氨的过程对于管理排放中的氮水平至关重要。这有助于防止过量氮释放到水体中,从而引发有害的藻类暴发,降低水质。总之,氨化过程在各种生物和生态过程中的重要作用。从提高农业土壤肥力到维持生态系统的平衡以及废物管理,理解和利用氨化可以带来显著的好处。随着我们继续探索生命及其化学基础的复杂性,像氨化这样的过程的重要性无疑将始终处于科学研究和实际应用的前沿。