pyrrolic
简明释义
叽咯(一种五倍杂环混合物)
英英释义
Relating to or derived from pyrrole, a five-membered aromatic heterocyclic compound. | 与吡咯相关或来源于吡咯,这是一种五元芳香杂环化合物。 |
单词用法
吡咯氮 | |
吡咯环 | |
吡咯酸 | |
合成吡咯类化合物 | |
表征吡咯结构 | |
分析吡咯衍生物 |
同义词
吡咯基的 | Pyrrole-based compounds are often used in organic synthesis. | 吡咯基化合物常用于有机合成。 | |
含氮的 | Many nitrogen-containing heterocycles exhibit unique chemical properties. | 许多含氮杂环展现出独特的化学性质。 |
反义词
非吡咯类的 | The compound is classified as non-pyrrolic due to its structure. | 由于其结构,该化合物被归类为非吡咯类的。 | |
脂肪族的 | Aliphatic compounds are generally more stable than pyrrolic ones. | 脂肪族化合物通常比吡咯类化合物更稳定。 |
例句
1.As nonhydrocarbons, pyrrolic compounds can also be used to distinguish genetic types of crude oils, this is similar to hydrocarbons.
与烃类化合物类似,非烃中吡咯类化合物可用于反映原油的成因类型。
2.As nonhydrocarbons, pyrrolic compounds can also be used to distinguish genetic types of crude oils, this is similar to hydrocarbons.
与烃类化合物类似,非烃中吡咯类化合物可用于反映原油的成因类型。
3.The chemist studied the properties of pyrrolic compounds for their potential use in organic synthesis.
化学家研究了吡咯类化合物的性质,以便它们在有机合成中的潜在应用。
4.Researchers found that pyrrolic derivatives can act as effective catalysts in various reactions.
研究人员发现,吡咯类衍生物可以在各种反应中作为有效的催化剂。
5.The presence of pyrrolic structures in the molecule contributed to its unique color.
分子中存在的吡咯类结构使其具有独特的颜色。
6.In her thesis, she explored the biological activity of pyrrolic compounds.
在她的论文中,她探讨了吡咯类化合物的生物活性。
7.The team synthesized a new pyrrolic compound that showed promise in treating certain diseases.
团队合成了一种新的吡咯类化合物,显示出在治疗某些疾病方面的前景。
作文
In the realm of organic chemistry, there are numerous fascinating compounds that exhibit unique properties and reactivities. One such class of compounds that has piqued the interest of chemists is that of the pyrrolic (吡咯类的) compounds. These compounds, characterized by their five-membered heterocyclic ring containing one nitrogen atom, play a crucial role in various biological systems and synthetic processes. Understanding the structure and function of pyrrolic (吡咯类的) compounds is essential for both academic research and industrial applications. The basic structure of a pyrrolic (吡咯类的) compound consists of a five-membered ring made up of four carbon atoms and one nitrogen atom. This unique arrangement gives pyrrolic (吡咯类的) compounds their distinctive properties, including their ability to participate in various chemical reactions. For instance, pyrrolic (吡咯类的) compounds can undergo oxidation, which allows them to be transformed into other useful substances. This reactivity makes them valuable intermediates in the synthesis of complex molecules, including pharmaceuticals and agrochemicals. One notable example of a pyrrolic (吡咯类的) compound is protoporphyrin IX, which is a precursor to heme, the iron-containing compound found in hemoglobin. The biological significance of pyrrolic (吡咯类的) compounds cannot be overstated, as they are involved in crucial physiological processes such as oxygen transport and electron transfer in cellular respiration. The intricate relationship between pyrrolic (吡咯类的) compounds and life itself highlights the importance of studying these compounds in greater detail. In addition to their biological relevance, pyrrolic (吡咯类的) compounds have also garnered attention in the field of materials science. Researchers have explored the potential of pyrrolic (吡咯类的) polymers in creating conductive materials, sensors, and even organic solar cells. The versatility of pyrrolic (吡咯类的) compounds allows scientists to tailor their properties for specific applications, making them a subject of ongoing research and development. Moreover, the study of pyrrolic (吡咯类的) compounds has led to advancements in our understanding of various diseases. For example, abnormalities in heme metabolism, which involves pyrrolic (吡咯类的) compounds, can result in conditions such as porphyria. By investigating the pathways involving pyrrolic (吡咯类的) compounds, researchers can develop new diagnostic tools and therapeutic strategies to combat these disorders. In conclusion, the exploration of pyrrolic (吡咯类的) compounds reveals their multifaceted nature and significance in both nature and technology. From their fundamental role in biological systems to their potential applications in materials science, pyrrolic (吡咯类的) compounds are a testament to the intricate connections between chemistry and life. As research continues to uncover new aspects of these compounds, we can expect to see further innovations that harness their unique properties for the benefit of society.
在有机化学领域,有许多迷人的化合物展现出独特的性质和反应性。其中一个引起化学家兴趣的化合物类别是吡咯类的化合物。这些化合物以其含有一个氮原子的五元杂环为特征,在各种生物系统和合成过程中发挥着关键作用。理解吡咯类的化合物的结构和功能对于学术研究和工业应用至关重要。 吡咯类的化合物的基本结构由四个碳原子和一个氮原子组成的五元环构成。这种独特的排列赋予了吡咯类的化合物其独特的性质,包括参与各种化学反应的能力。例如,吡咯类的化合物可以发生氧化反应,使它们转变为其他有用物质。这种反应性使它们成为复杂分子合成中的宝贵中间体,包括药物和农用化学品。 一个值得注意的吡咯类的化合物的例子是原卟啉IX,它是血红素的前体,血红素是存在于血红蛋白中的含铁化合物。吡咯类的化合物在生物学上的重要性不可低估,因为它们参与了诸如氧气运输和细胞呼吸中的电子转移等重要生理过程。吡咯类的化合物与生命之间的复杂关系突显了深入研究这些化合物的重要性。 除了生物相关性,吡咯类的化合物在材料科学领域也引起了关注。研究人员探索了吡咯类的聚合物在创建导电材料、传感器甚至有机太阳能电池中的潜力。吡咯类的化合物的多功能性使科学家能够根据特定应用调整其性质,使其成为持续研究和开发的主题。 此外,吡咯类的化合物的研究促进了我们对各种疾病的理解。例如,血红素代谢异常(涉及吡咯类的化合物)可能导致如卟啉症等疾病。通过研究涉及吡咯类的化合物的途径,研究人员可以开发新的诊断工具和治疗策略,以对抗这些疾病。 总之,探索吡咯类的化合物揭示了它们在自然和技术中的多面性及重要性。从它们在生物系统中的基本作用到在材料科学中的潜在应用,吡咯类的化合物证明了化学与生命之间的复杂联系。随着研究继续揭示这些化合物的新方面,我们可以期待看到进一步的创新,利用它们独特的性质造福社会。
文章标题:pyrrolic的意思是什么
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