quinonoid

简明释义

英[ˈkwɪnəˌnɔɪd]美[ˈkwɪnəˌnɔɪd;kwɪˈnoʊnɔɪd]

adj. 醌型的

英英释义

单词用法

同义词

反义词

例句

1.Various hue assemblies are vogues, the picture element quinonoid formula hue will be greatly hot.

多种色彩组合是风尚，像素式色彩会大热。

2.The new fluorescent band is considered to be related to the intramolecular charge transfer between the amino group and the quinonoid carbonyl group.

我们认为该新的荧光峰与胺基和醌羰基之间的分子内电子转移有关。

3.At familiar alcohol extent quinonoid formula in, pour wine, wish alcoholic and toast appliance maximum.

在常见的饮酒程度式之中，斟酒、祝酒、干杯应用最多。

4.The new fluorescent band is considered to be related to the intramolecular charge transfer between the amino group and the quinonoid carbonyl group.

我们认为该新的荧光峰与胺基和醌羰基之间的分子内电子转移有关。

5.In organic chemistry, quinonoid compounds are often used as intermediates in various reactions.

在有机化学中，醌类化合物常被用作各种反应的中间体。

6.The chemist synthesized a new compound with a quinonoid structure, which showed promising results in preliminary tests.

化学家合成了一种具有醌类结构的新化合物，在初步测试中显示出良好的结果。

7.The presence of a quinonoid moiety can significantly alter the electronic properties of a molecule.

一个醌类部分的存在可以显著改变分子的电子性质。

8.The color change observed in the reaction was attributed to the formation of a quinonoid species.

反应中观察到的颜色变化归因于醌类物种的形成。

9.Researchers discovered that the quinonoid form of the dye has a higher stability than its non-quinonoid counterpart.

研究人员发现该染料的醌类形式比其非醌类对应物更稳定。

作文

In the world of organic chemistry, there are various compounds that play crucial roles in numerous reactions and processes. One such compound is the quinonoid, which is a type of chemical structure that exhibits specific properties and characteristics. Understanding the nature of quinonoid compounds can provide insights into their applications in various fields, including medicine, materials science, and environmental studies.A quinonoid structure typically contains a conjugated system of double bonds, which allows for resonance stabilization. This means that the electrons within the quinonoid structure can be delocalized, resulting in increased stability and unique reactivity. The presence of a quinonoid structure can significantly influence the behavior of the molecule in chemical reactions, making it an important subject of study for chemists.One of the most well-known examples of quinonoid compounds is benzoquinone, which is derived from benzene. Benzoquinone is not only interesting from a chemical standpoint but also has practical applications. It is used in the synthesis of various dyes and pigments, which are essential in industries such as textiles and printing. Additionally, benzoquinone plays a role in biological systems, particularly in photosynthesis, where it participates in electron transport processes.The versatility of quinonoid compounds extends beyond benzoquinone. Many natural products, including certain alkaloids and flavonoids, contain quinonoid structures. These compounds often exhibit significant biological activity, which makes them valuable in pharmaceutical research. For instance, some quinonoid derivatives have been studied for their potential anti-cancer properties, showcasing the importance of this class of compounds in drug development.Moreover, the study of quinonoid compounds is not limited to their chemical properties; their physical properties are equally fascinating. The color of many quinonoid compounds is often intense, which is attributed to their electronic structure. This characteristic has led to their use in the development of organic light-emitting diodes (OLEDs) and other optoelectronic devices. The ability to manipulate the electronic properties of quinonoid compounds opens up new avenues for technological advancements and innovations.In conclusion, the study of quinonoid compounds is essential for understanding their role in both natural and synthetic processes. From their unique chemical properties to their potential applications in various industries, quinonoid structures offer a wealth of knowledge and opportunities for further exploration. As research continues to uncover the complexities of these compounds, we can expect to see even more innovative uses and applications emerge, solidifying the importance of quinonoid chemistry in the broader context of science and technology.Overall, the significance of quinonoid compounds cannot be overstated. Their diverse applications in medicine, materials science, and technology highlight the need for continued research and understanding of their properties. By delving deeper into the world of quinonoid structures, scientists and researchers can unlock new possibilities that may lead to breakthroughs in various fields, ultimately benefiting society as a whole.

在有机化学的世界中，有各种化合物在众多反应和过程中发挥着至关重要的作用。其中一种化合物是quinonoid，这是一种具有特定属性和特征的化学结构。理解quinonoid化合物的性质可以为其在医学、材料科学和环境研究等各个领域的应用提供见解。quinonoid结构通常包含一个共轭的双键体系，这使得共振稳定性得以实现。这意味着quinonoid结构中的电子可以离域，从而导致增加的稳定性和独特的反应性。quinonoid结构的存在可以显著影响分子在化学反应中的行为，使其成为化学家研究的重要课题。最著名的quinonoid化合物之一是苯醌，它是由苯衍生而来的。苯醌不仅从化学角度上有趣，而且具有实际应用。它用于合成各种染料和颜料，这些在纺织和印刷等行业中至关重要。此外，苯醌在生物系统中也起着作用，特别是在光合作用中，它参与了电子传输过程。quinonoid化合物的多样性不仅限于苯醌。许多天然产物，包括某些生物碱和黄酮类，含有quinonoid结构。这些化合物往往表现出显著的生物活性，使它们在药物研究中非常有价值。例如，一些quinonoid衍生物已被研究其潜在的抗癌特性，展示了这一类化合物在药物开发中的重要性。此外，对quinonoid化合物的研究不仅限于它们的化学性质；它们的物理性质同样引人入胜。许多quinonoid化合物的颜色通常很强烈，这归因于它们的电子结构。这一特性使它们在有机发光二极管（OLED）和其他光电设备的开发中得到了应用。操控quinonoid化合物的电子性质的能力为技术进步和创新开辟了新的途径。总之，研究quinonoid化合物对于理解它们在自然和合成过程中的作用至关重要。从它们独特的化学性质到它们在各个行业中的潜在应用，quinonoid结构提供了丰富的知识和进一步探索的机会。随着研究继续揭示这些化合物的复杂性，我们可以期待看到更多创新的用途和应用出现，从而巩固quinonoid化学在更广泛的科学和技术背景中的重要性。总体而言，quinonoid化合物的重要性不容低估。它们在医学、材料科学和技术中的多样化应用突显了对其性质继续研究和理解的必要性。通过深入探讨quinonoid结构的世界，科学家和研究人员可以解锁新的可能性，可能导致各个领域的突破，最终惠及整个社会。