azotized

简明释义

英[ˈæzətaɪzd]美[ˈæzəˌtaɪzd]

adj. 含氮的

v. 使氮化（azotiz 的过去式和过去分词形式）

英英释义

单词用法

同义词

反义词

例句

1.And the azotized silicon product has won the honorary title of national new product for the year of1995.

氮化硅制品获得1995年度国家级新产品荣誉称号。

2.And the azotized silicon product has won the honorary title of national new product for the year of1995.

氮化硅制品获得1995年度国家级新产品荣誉称号。

3.The azotized silicon factory possesses the domestic advanced azotized silicon sintering equipments.

氮化硅厂拥有国内先进的氮化硅烧结设备。

4.The soil was enriched with azotized 氮化的 fertilizers to boost plant growth.

土壤通过施用azotized 氮化的 化肥来增强植物生长。

5.Farmers often use azotized 氮化的 compost to improve the nitrogen content of their crops.

农民们常常使用azotized 氮化的 堆肥来提高作物的氮含量。

6.The research indicated that azotized 氮化的 compounds can enhance soil fertility.

研究表明，azotized 氮化的 化合物可以提高土壤肥力。

7.In the lab, they created an azotized 氮化的 solution for their experiments.

在实验室，他们为实验创建了一种azotized 氮化的 溶液。

8.The process of making azotized 氮化的 materials is crucial for agricultural development.

制造azotized 氮化的 材料的过程对农业发展至关重要。

作文

In the realm of chemistry and biology, the term azotized refers to a process involving the introduction of nitrogen into organic compounds. This transformation is crucial for various applications, especially in agriculture and pharmaceuticals. Understanding the significance of azotized compounds can provide insights into the broader implications of nitrogen in our ecosystem. Nitrogen is a fundamental element that plays a vital role in the growth and development of plants. It is a key component of amino acids, which are the building blocks of proteins. When we talk about azotized substances, we are often referring to those that have undergone a process where nitrogen is incorporated into their structure. This can enhance the nutritional value of fertilizers, making them more effective in promoting plant growth. For instance, when fertilizers are azotized, they can release nitrogen slowly, providing a steady supply of this essential nutrient to crops over time. Moreover, azotized compounds are not only important in agriculture but also have significant implications in the pharmaceutical industry. Many drugs are synthesized using nitrogen-containing compounds, and understanding how to manipulate these compounds can lead to the development of more effective medications. The ability to create azotized derivatives allows chemists to design molecules that can interact with biological systems in specific ways, potentially leading to breakthroughs in treating various diseases. The process of azotization itself can vary depending on the desired outcome. It may involve chemical reactions that introduce nitrogen in different forms, such as amines or nitrates. These reactions are carefully controlled to ensure that the resulting azotized compounds possess the intended properties. For example, in the production of certain fertilizers, the nitrogen must be in a form that plants can readily absorb. This requires a deep understanding of both chemistry and plant biology, highlighting the interdisciplinary nature of modern scientific research. Furthermore, the environmental impact of azotized compounds cannot be overlooked. While nitrogen is essential for plant growth, excessive use of nitrogen-based fertilizers can lead to problems such as water pollution and soil degradation. Therefore, researchers are continually exploring ways to optimize the use of azotized fertilizers to minimize environmental harm while maximizing agricultural productivity. This balance is crucial in the context of sustainable farming practices, where the goal is to meet the food demands of a growing population without compromising the health of our planet. In conclusion, the term azotized encapsulates a critical process that bridges the fields of chemistry, biology, and environmental science. By incorporating nitrogen into organic compounds, azotized substances play an essential role in enhancing agricultural productivity and developing pharmaceutical innovations. As we continue to explore the potential of nitrogen in various applications, it is imperative to consider both the benefits and the environmental consequences associated with its use. Ultimately, a deeper understanding of azotized compounds will contribute to more sustainable practices in both agriculture and medicine, ensuring a healthier future for generations to come.

在化学和生物学领域，术语azotized指的是将氮引入有机化合物的过程。这种转化对于农业和制药等多个应用至关重要。理解azotized化合物的重要性可以为我们提供关于氮在生态系统中更广泛影响的见解。 氮是一种基本元素，在植物的生长和发育中发挥着至关重要的作用。它是氨基酸的关键成分，而氨基酸是蛋白质的构建块。当我们谈论azotized物质时，通常是指那些经过氮被纳入其结构的过程。这可以提高肥料的营养价值，使其在促进植物生长方面更加有效。例如，当肥料被azotized时，它们可以缓慢释放氮，为作物提供持续的这种必需营养素。 此外，azotized化合物不仅在农业中重要，而且在制药行业也具有重大意义。许多药物是通过氮含量化合物合成的，了解如何操控这些化合物可以导致更有效药物的开发。创造azotized衍生物的能力使化学家能够设计与生物系统以特定方式相互作用的分子，这可能导致治疗各种疾病的突破。 azotization的过程本身可能因所需结果而异。它可能涉及化学反应，将氮以不同形式引入，例如胺或硝酸盐。这些反应经过精心控制，以确保所得到的azotized化合物具有预期的性质。例如，在某些肥料的生产中，氮必须处于植物可以轻易吸收的形式。这需要对化学和植物生物学有深入的理解，突显了现代科学研究的跨学科性质。 此外，azotized化合物的环境影响也不能被忽视。虽然氮对植物生长至关重要，但过量使用氮基肥料可能导致水污染和土壤退化等问题。因此，研究人员不断探索优化azotized肥料使用的方法，以最小化环境危害，同时最大化农业生产力。这种平衡在可持续农业实践的背景下至关重要，其目标是在不损害地球健康的情况下满足日益增长的人口的食品需求。 总之，术语azotized概括了一种连接化学、生物学和环境科学的关键过程。通过将氮纳入有机化合物，azotized物质在提升农业生产力和开发制药创新中发挥着重要作用。随着我们继续探索氮在各种应用中的潜力，考虑其使用的好处和环境后果是至关重要的。最终，对azotized化合物的更深入理解将有助于农业和医学中更可持续的实践，确保为未来几代人创造一个更健康的未来。