azotic

简明释义

英[eɪˈzɒtɪk]美[əˈzɑːtɪk]

含氮的

英英释义

单词用法

同义词

反义词

例句

1.Hu Pilan can absorb azotic oxide and methane gas.

虎皮兰能吸收氮氧化物和甲烷气体。

2.Hu Pilan can absorb azotic oxide and methane gas.

虎皮兰能吸收氮氧化物和甲烷气体。

3.The soil in this region is particularly rich in azotic 氮的 compounds, making it ideal for farming.

该地区的土壤中富含azotic 氮的化合物，非常适合农业。

4.Researchers are studying the effects of azotic 氮的 fertilizers on crop yields.

研究人员正在研究azotic 氮的肥料对作物产量的影响。

5.In aquaculture, maintaining an appropriate level of azotic 氮的 content is crucial for fish health.

在水产养殖中，维持适当的azotic 氮的含量对鱼类健康至关重要。

6.The presence of azotic 氮的 bacteria in the water can help improve its quality.

水中存在的azotic 氮的细菌可以帮助改善水质。

7.Farmers often rely on azotic 氮的 cover crops to enhance soil fertility.

农民常常依赖于azotic 氮的覆盖作物来提高土壤肥力。

作文

In the realm of chemistry and environmental science, the term azotic refers to a state that is related to nitrogen. Nitrogen, as we know, is an essential element for life, playing a crucial role in the formation of amino acids and nucleic acids. The significance of nitrogen cannot be overstated; it constitutes about 78% of the Earth's atmosphere and is a key component in various biological processes. Understanding the concept of azotic is vital for those studying ecology, agriculture, and biochemistry. One of the most fascinating aspects of nitrogen is its cycle in nature. The nitrogen cycle involves several processes, including fixation, nitrification, denitrification, and ammonification. In this context, the term azotic becomes particularly relevant. For instance, certain bacteria in the soil are capable of fixing atmospheric nitrogen, converting it into forms that plants can absorb. This process is essential for plant growth and is a fundamental principle in sustainable agriculture. Without these azotic processes, our crops would struggle to thrive, leading to food shortages and ecological imbalances. Moreover, the role of azotic compounds extends beyond agriculture. In the field of environmental science, understanding how nitrogen compounds affect ecosystems is crucial. For example, excess nitrogen from fertilizers can lead to water pollution, causing algal blooms that deplete oxygen in water bodies, negatively impacting aquatic life. This phenomenon highlights the importance of managing nitrogen levels in our environment and ensuring that azotic substances are used responsibly. In addition to its environmental implications, the study of azotic compounds is also significant in human health. Certain nitrogen-containing compounds can be harmful if ingested or inhaled, leading to various health issues. Therefore, researchers are continuously exploring the effects of azotic pollutants in air and water to develop better regulations and protective measures. As we delve deeper into the science of nitrogen, it becomes evident that the term azotic encapsulates a wide range of phenomena that are critical to our existence. From supporting plant life to influencing ecosystem dynamics and impacting human health, nitrogen and its azotic derivatives play a pivotal role in maintaining the balance of life on Earth. To fully appreciate the complexity of these interactions, one must engage in interdisciplinary studies that encompass biology, chemistry, and environmental science. In conclusion, the term azotic serves as a reminder of the intricate connections between different scientific fields and the importance of nitrogen in our world. By fostering a deeper understanding of azotic processes, we can better address the challenges associated with agriculture, environmental conservation, and public health. As we move forward, it is essential to prioritize research and education on azotic compounds to ensure a sustainable future for generations to come.

在化学和环境科学领域，术语azotic指的是与氮相关的状态。氮，正如我们所知，是生命的基本元素，在氨基酸和核酸的形成中发挥着至关重要的作用。氮的重要性不言而喻；它占地球大气的约78%，并且是各种生物过程中的关键组成部分。理解azotic的概念对于那些研究生态学、农业和生物化学的人来说至关重要。 氮最引人入胜的方面之一是其在自然界中的循环。氮循环涉及几个过程，包括固氮、硝化、反硝化和铵化。在这个背景下，术语azotic变得特别相关。例如，土壤中的某些细菌能够固定大气中的氮，将其转化为植物可以吸收的形式。这个过程对植物生长至关重要，是可持续农业的基本原则。如果没有这些azotic过程，我们的作物将难以茁壮成长，导致粮食短缺和生态失衡。 此外，azotic化合物的作用不仅限于农业。在环境科学领域，了解氮化合物如何影响生态系统至关重要。例如，来自化肥的过量氮会导致水污染，引发藻类繁殖，消耗水体中的氧气，负面影响水生生物。这一现象突显了管理我们环境中氮水平的重要性，确保azotic物质得到负责任的使用。 除了其环境影响外，研究azotic化合物在人体健康中的重要性也不可忽视。某些含氮化合物如果被摄入或吸入，可能会造成伤害，导致各种健康问题。因此，研究人员不断探索azotic污染物在空气和水中的影响，以制定更好的法规和保护措施。 随着我们深入研究氮的科学，显而易见的是，术语azotic概括了对我们生存至关重要的广泛现象。从支持植物生命到影响生态系统动态，再到影响人类健康，氮及其azotic衍生物在维持地球生命的平衡中发挥着关键作用。要充分欣赏这些相互作用的复杂性，必须参与跨学科的研究，涵盖生物学、化学和环境科学。 总之，术语azotic提醒我们不同科学领域之间的复杂联系以及氮在我们世界中的重要性。通过加深对azotic过程的理解，我们可以更好地应对与农业、环境保护和公共健康相关的挑战。展望未来，优先进行关于azotic化合物的研究和教育，对于确保后代可持续的未来至关重要。