oxazine
简明释义
n. 嗪;恶嗪染料
英英释义
Oxazine is a heterocyclic compound containing a six-membered ring with one oxygen and one nitrogen atom. | 氧杂啉是一种含有一个氧原子和一个氮原子的六元环的杂环化合物。 |
单词用法
同义词
| 苯并噁嗪 | Benzoxazine derivatives are commonly used in polymer chemistry. | 苯并噁嗪衍生物常用于聚合物化学。 | |
| 噁唑烷 | Oxazolidine compounds are often utilized in medicinal chemistry. | 噁唑烷化合物常用于药物化学。 |
反义词
| 非氧杂环 | 非氧杂环化合物常用于有机合成。 | ||
| 烷烃 | Alkanes are saturated hydrocarbons that do not contain any heteroatoms. | 烷烃是饱和烃,不含任何杂原子。 |
例句
1.The fluorescence quantum efficiency of oxazine 1perohlorate in1-dichloro-ethane was measured with photoacoustic speetroscopy in which the fluorescence quenching wag used.
利用光声光谱技术,采取猝灭的方法对(口恶)嗪1高氯酸盐的二氯乙烷溶液进行荧光量子效率的测量。
2.The invention discloses an anti-influenza virus prodrug which is a derivative related to 1, 3-pyrazine oxazine-2, 4 diketone with a chemical structural formula (I);
本发明公开了一种抗流感病毒前体药,是有关1,3-吡嗪并恶 嗪-2,4二酮的衍生物,其化学结构式为;
3.Conclusion The modification of a 1,4-oxazine-2-one ring fused with positions 9 and 10 of A-ring will reduce the antitumor activity of camptothecins.
结论喜树碱A环的9,10位增加一个“1,4 氧嗪2 酮”六元环后,其抗肿瘤活性要比喜树碱或10 羟基喜树碱的活性降低。
4.The fluorescence quantum efficiency of oxazine 1perohlorate in1-dichloro-ethane was measured with photoacoustic speetroscopy in which the fluorescence quenching wag used.
利用光声光谱技术,采取猝灭的方法对(口恶)嗪1高氯酸盐的二氯乙烷溶液进行荧光量子效率的测量。
5.A novel oxazine 氧杂环 compound was discovered that exhibits anti-cancer properties.
发现了一种新型的oxazine 氧杂环化合物,具有抗癌特性。
6.The research focused on the reactivity of oxazine 氧杂环 in various solvents.
研究集中在不同溶剂中oxazine 氧杂环的反应性上。
7.The application of oxazine 氧杂环 in medicinal chemistry has gained significant attention.
在药物化学中,oxazine 氧杂环的应用引起了广泛关注。
8.The chemist synthesized a new compound based on the structure of oxazine 氧杂环 to improve its properties.
化学家合成了一种基于oxazine 氧杂环结构的新化合物,以改善其性能。
9.In organic chemistry, oxazine 氧杂环 derivatives are often used as fluorescent dyes.
在有机化学中,oxazine 氧杂环衍生物常被用作荧光染料。
作文
The world of chemistry is filled with fascinating compounds, each with unique properties and applications. One such compound that has garnered attention in recent years is oxazine, a heterocyclic organic compound that contains both nitrogen and oxygen atoms in its ring structure. Understanding oxazine is essential for chemists and researchers, as it plays a significant role in various fields, including pharmaceuticals, dyes, and materials science.Oxazine is characterized by its six-membered ring containing one nitrogen atom and one oxygen atom. This unique structure allows for a variety of chemical reactions, making oxazine versatile in synthetic chemistry. For instance, derivatives of oxazine have been used to develop new drugs that target specific diseases, showcasing its importance in medicinal chemistry.Moreover, the optical properties of oxazine compounds are noteworthy. Many oxazine derivatives exhibit interesting colorimetric properties, which makes them valuable as dyes and pigments. These compounds can be used in textiles, plastics, and even in art materials, allowing artists to explore vibrant colors and shades.In addition to its applications in pharmaceuticals and dyes, oxazine is also significant in the field of materials science. Researchers are exploring the use of oxazine as a building block for creating new polymers with enhanced properties. The incorporation of oxazine units into polymer chains can lead to materials with improved thermal stability and mechanical strength, which are crucial for various industrial applications.Furthermore, the study of oxazine is not limited to its practical applications; it also provides insight into the fundamental aspects of organic chemistry. The reactivity of oxazine compounds can help chemists understand reaction mechanisms and the behavior of heterocycles in chemical processes. By studying oxazine, researchers can gain a deeper understanding of how molecular structures influence reactivity and stability.As the demand for innovative materials and pharmaceuticals continues to grow, the importance of oxazine and its derivatives will likely increase. Ongoing research aims to uncover new uses for oxazine compounds, pushing the boundaries of what is possible in chemistry. In conclusion, oxazine is more than just a chemical compound; it is a key player in advancing various scientific fields. Its diverse applications and intriguing chemical properties make it a subject of great interest for chemists worldwide.Overall, the journey of understanding oxazine reflects the broader narrative of chemistry: a continuous exploration of substances that shape our world. As we delve deeper into the complexities of oxazine and its derivatives, we unveil new possibilities that can contribute to technological advancements and improve our quality of life.
化学世界充满了迷人的化合物,每种化合物都有独特的性质和应用。其中一种近年来备受关注的化合物是oxazine,一种含有氮和氧原子的杂环有机化合物。理解oxazine对化学家和研究人员至关重要,因为它在制药、染料和材料科学等多个领域发挥着重要作用。Oxazine的特点是其六元环中含有一个氮原子和一个氧原子。这种独特的结构允许进行各种化学反应,使oxazine在合成化学中具有多种用途。例如,oxazine的衍生物已被用于开发针对特定疾病的新药,展示了其在药物化学中的重要性。此外,oxazine化合物的光学性质也值得注意。许多oxazine衍生物表现出有趣的颜色特性,这使得它们作为染料和颜料变得有价值。这些化合物可以用于纺织品、塑料,甚至艺术材料,让艺术家探索生动的颜色和色调。除了在制药和染料中的应用外,oxazine在材料科学领域也很重要。研究人员正在探索将oxazine用作新型聚合物的构建块,以增强其性能。在聚合物链中加入oxazine单元可以导致具有更好热稳定性和机械强度的材料,这对于各种工业应用至关重要。此外,oxazine的研究不仅限于其实际应用;它还提供了对有机化学基本方面的洞察。Oxazine化合物的反应性可以帮助化学家理解反应机制和杂环在化学过程中的行为。通过研究oxazine,研究人员可以更深入地了解分子结构如何影响反应性和稳定性。随着对创新材料和药物需求的不断增长,oxazine及其衍生物的重要性可能会增加。正在进行的研究旨在揭示oxazine化合物的新用途,推动化学领域的边界。总之,oxazine不仅仅是一种化学化合物;它是推动各个科学领域进步的关键参与者。其多样的应用和引人入胜的化学性质使其成为全球化学家极感兴趣的研究对象。总体而言,理解oxazine的旅程反映了化学的更广泛叙事:对塑造我们世界的物质的持续探索。当我们深入探讨oxazine及其衍生物的复杂性时,我们揭示了新的可能性,这些可能性可以促进技术进步并改善我们的生活质量。
