azine

简明释义

英[ˈeɪziːn]美[ˈeɪzɪn]

n. 吖嗪；连氮

英英释义

单词用法

同义词

反义词

例句

1.A new method of preparation of 2-amino-4 -methylamino-6-ethoxys-tri - azine is found. And the optimum reaction conditions are determined by orthogonal experiments. The total yield is 61.5%.

通过实验设计出一条新的合成2-氨基- 4 -甲氨基- 6 -乙氧基均三嗪的路线，并经过正交实验确定了最佳反应条件，产品总收率为61.5%。

2.A new method of preparation of 2-amino-4 -methylamino-6-ethoxys-tri - azine is found. And the optimum reaction conditions are determined by orthogonal experiments. The total yield is 61.5%.

通过实验设计出一条新的合成2-氨基- 4 -甲氨基- 6 -乙氧基均三嗪的路线，并经过正交实验确定了最佳反应条件，产品总收率为61.5%。

3.Abstract the review discusses many ways of preparing hydrazine through hydrolysis of azine, and the effects of catalyst to yield of hydrazine by hydrolyzing azine.

摘要文中讨论了酮连氮水解制备肼的各种方法及催化剂对酮连氮水解和肼收率的影响。

4.The review discusses many ways of preparing hydrazine through hydrolysis of azine, and the effects of catalyst to yield of hydrazine by hydrolyzing azine.

文中讨论了酮连氮水解制备肼的各种方法及催化剂对酮连氮水解和肼收率的影响。

5.The review discusses many ways of preparing hydrazine through hydrolysis of azine, and the effects of catalyst to yield of hydrazine by hydrolyzing azine.

摘要文中讨论了酮连氮水解制备肼的各种方法及催化剂对酮连氮水解和肼收率的影响。

6.The coordination of azine with salts of transition metal were investigated and 10 new complexes were prepared.

研究了吖嗪化合物与过渡金属盐络合作用，得到了10个新吖嗪配合物。

7.The chemist synthesized a new compound that included an azine structure, which is known for its stability.

化学家合成了一种新化合物，其中包含azine结构，因其稳定性而闻名。

8.In drug development, many medications are derived from azine derivatives due to their effectiveness.

在药物开发中，许多药物是由azine衍生物衍生而来的，因其有效性。

9.The research paper discussed the properties of various azine compounds in organic chemistry.

研究论文讨论了有机化学中各种azine化合物的性质。

10.During the laboratory experiment, we observed the reaction of an azine with different reagents.

在实验室实验中，我们观察到azine与不同试剂的反应。

11.The pharmaceutical company is focusing on azine based drugs for treating mental health disorders.

制药公司专注于开发用于治疗心理健康障碍的azine类药物。

作文

In the world of chemistry, the term azine refers to a class of compounds that are characterized by the presence of a nitrogen atom in a six-membered aromatic ring. These compounds play a significant role in various chemical reactions and are crucial for the synthesis of many pharmaceuticals. Understanding the structure and properties of azine compounds is essential for chemists who are involved in drug development and research. For instance, some azine derivatives are known for their effectiveness as antidepressants or antipsychotics, showcasing their importance in medicinal chemistry. The basic structure of an azine consists of a benzene ring with a nitrogen atom replacing one of the carbon atoms. This substitution alters the electronic properties of the ring, making azine compounds unique and versatile in their applications. The presence of the nitrogen atom introduces basicity and can influence the reactivity of the compound, allowing for a range of chemical transformations. One of the most well-known examples of an azine compound is phenothiazine, which is used in the treatment of schizophrenia and other mental health disorders. The discovery of this compound opened up new avenues for psychiatric treatment and highlighted the potential of azine derivatives in pharmacology. As researchers continue to explore the vast landscape of azine chemistry, they uncover new compounds that may lead to breakthroughs in medical science. Moreover, azine compounds are not limited to medicinal use; they also find applications in agriculture as pesticides and herbicides. The ability of these compounds to interact with biological systems makes them valuable tools in crop protection. By understanding how azine derivatives function at a molecular level, scientists can design more effective and environmentally friendly agricultural chemicals. In addition to their practical applications, azine compounds also serve as important subjects of study in theoretical chemistry. Researchers investigate their electronic structures, reaction mechanisms, and potential interactions with other molecules. This fundamental research contributes to our overall understanding of chemical principles and helps to refine the methods used in synthetic chemistry. As we delve deeper into the study of azine compounds, it becomes clear that they are a vital part of modern chemistry. Their diverse applications in medicine, agriculture, and research underscore the importance of continued exploration in this area. By fostering a greater understanding of azine chemistry, we can unlock new possibilities for innovation and improve the quality of life for people around the world. In conclusion, the significance of azine compounds cannot be overstated. They are integral to various fields, from pharmaceuticals to agriculture, and their unique properties make them a focus of ongoing research. As we continue to learn more about these fascinating compounds, we pave the way for future advancements that can benefit society as a whole.

在化学的世界中，术语azine指的是一类化合物，其特征是在六元芳香环中存在一个氮原子。这些化合物在各种化学反应中起着重要作用，并且对许多药物的合成至关重要。理解azine化合物的结构和性质对于参与药物开发和研究的化学家来说至关重要。例如，一些azine衍生物以其作为抗抑郁药或抗精神病药的有效性而闻名，展示了它们在药物化学中的重要性。 azine的基本结构由一个苯环构成，其中一个碳原子被氮原子取代。这种取代改变了环的电子性质，使得azine化合物在应用上独特而多样。氮原子的存在引入了碱性，并可能影响化合物的反应性，从而允许进行一系列化学转化。 一个众所周知的azine化合物的例子是酚噻嗪，它用于治疗精神分裂症和其他心理健康障碍。这种化合物的发现开启了精神病治疗的新途径，并突显了azine衍生物在药理学中的潜力。当研究人员继续探索azine化学的广阔领域时，他们会发现新的化合物，这些化合物可能导致医学科学的突破。 此外，azine化合物不仅限于药用；它们还在农业中作为农药和除草剂找到应用。这些化合物与生物系统相互作用的能力使它们成为作物保护的宝贵工具。通过理解azine衍生物在分子水平上的功能，科学家可以设计出更有效且环保的农业化学品。 除了实际应用之外，azine化合物也作为理论化学的重要研究对象。研究人员调查它们的电子结构、反应机制以及与其他分子的潜在相互作用。这一基础研究有助于我们对化学原理的整体理解，并帮助完善合成化学中使用的方法。 随着我们深入研究azine化合物，显然它们是现代化学的重要组成部分。它们在医学、农业和研究中的多样应用强调了在这一领域持续探索的重要性。通过促进对azine化学的更大理解，我们可以解锁创新的新可能性，并改善全球人民的生活质量。 总之，azine化合物的重要性不容小觑。它们是多个领域的核心，从制药到农业，其独特的性质使它们成为持续研究的重点。随着我们对这些迷人化合物了解的不断加深，我们为未来的进步铺平了道路，这些进步能够惠及整个社会。