benzenoid
简明释义
adj. 苯(环)型的
英英释义
Relating to or resembling benzene or its derivatives, often characterized by a ring structure and delocalized electrons. | 与苯或其衍生物相关或相似,通常具有环状结构和离域电子的特征。 |
单词用法
苯环 | |
苯类烃 | |
苯类衍生物 | |
芳香苯类 | |
非苯类化合物 | |
类似苯的行为 |
同义词
反义词
例句
1.The products with higher conductivity are mainly 1, 4-connected head-to-tail chain structure, both benzenoid and quinoid units exist in the polymer chain.
具有较高电导的产物的链结构主要是1,4 -连接的头尾结构,链上同时存在苯式及醌式两种结构单元。
2.The products with higher conductivity are mainly 1, 4-connected head-to-tail chain structure, both benzenoid and quinoid units exist in the polymer chain.
具有较高电导的产物的链结构主要是1,4 -连接的头尾结构,链上同时存在苯式及醌式两种结构单元。
3.This mode of benzenoid synthesis is presented in the first part of this chapter.
这种合成苯衍生物的方法,将在本章第一部分介绍。
4.Method for preparing 1, 4-di (2, 4-diamino phenoxy) benzenoid form polyimide film for flexible copper clad plate.
柔性覆铜板用1,4 -双(2,4 -二氨基苯氧基)苯型聚酰亚胺薄膜的制备方法。
5.The presence of benzenoid 苯类 structures can influence the reactivity of chemical compounds.
存在benzenoid 苯类结构会影响化合物的反应性。
6.Many natural fragrances are derived from benzenoid 苯类 compounds found in flowers.
许多天然香料来源于花朵中发现的benzenoid 苯类化合物。
7.The compound has a distinct aroma due to its benzenoid 苯类 structure.
该化合物因其具有独特的香气,源于其benzenoid 苯类结构。
8.In organic chemistry, understanding benzenoid 苯类 systems is crucial for synthesizing complex molecules.
在有机化学中,理解benzenoid 苯类体系对于合成复杂分子至关重要。
9.Researchers are studying the effects of benzenoid 苯类 compounds on human health.
研究人员正在研究benzenoid 苯类化合物对人类健康的影响。
作文
In the realm of organic chemistry, the term benzenoid refers to a class of compounds that contain a benzene ring or are derived from benzene. Benzene itself is one of the simplest aromatic hydrocarbons, characterized by its unique structure and stability due to resonance. Understanding benzenoid compounds is crucial for chemists, as they play significant roles in various chemical reactions and applications. For instance, many dyes, pharmaceuticals, and polymers are based on benzenoid structures. These compounds exhibit distinct properties, such as high stability and the ability to undergo electrophilic substitution reactions, making them invaluable in synthetic organic chemistry.The significance of benzenoid compounds extends beyond their chemical properties; they are also pivotal in biological systems. Many natural products, including essential oils and alkaloids, possess benzenoid structures, contributing to their aroma and therapeutic effects. For example, the fragrance of jasmine and the medicinal properties of certain plants can be attributed to the presence of benzenoid compounds. This connection between chemistry and biology highlights the importance of understanding these structures in both fields.Moreover, the study of benzenoid compounds has led to advancements in materials science. Researchers have developed new materials with enhanced properties by modifying benzenoid structures. Conductive polymers, which are used in electronic devices, often incorporate benzenoid units to achieve desirable electrical properties. The versatility of benzenoid compounds allows scientists to innovate and create materials that meet the demands of modern technology.In addition to their practical applications, benzenoid compounds are also a subject of theoretical interest. Chemists explore the electronic structure and behavior of benzenoid systems using computational methods and spectroscopic techniques. These studies provide insights into the stability and reactivity of benzenoid compounds, enhancing our understanding of fundamental chemical principles.Despite their many advantages, the environmental impact of benzenoid compounds cannot be overlooked. Some benzenoid derivatives, such as polycyclic aromatic hydrocarbons (PAHs), are known to be toxic and carcinogenic. Therefore, researchers are actively investigating ways to mitigate the risks associated with these compounds while still harnessing their beneficial properties.In conclusion, the term benzenoid encompasses a wide range of compounds that are integral to both chemistry and biology. Their unique properties and diverse applications make them a focal point of research and innovation. As we continue to explore the potential of benzenoid compounds, it is essential to balance their benefits with environmental considerations. Understanding the complexities of benzenoid chemistry will undoubtedly pave the way for future discoveries and advancements in various scientific fields.
在有机化学领域,术语benzenoid指的是一类含有苯环或源自苯的化合物。苯本身是最简单的芳香烃之一,其独特的结构和由于共振而产生的稳定性使其具有特殊的性质。理解benzenoid化合物对化学家至关重要,因为它们在各种化学反应和应用中发挥着重要作用。例如,许多染料、药物和聚合物都是基于benzenoid结构的。这些化合物表现出显著的特性,如高度稳定性和进行亲电取代反应的能力,使它们在合成有机化学中无价。benzenoid化合物的重要性不仅体现在它们的化学性质上;它们在生物系统中也占据着关键地位。许多天然产物,包括精油和生物碱,具有benzenoid结构,促成了它们的香气和治疗效果。例如,茉莉花的香味和某些植物的药用特性可以归因于benzenoid化合物的存在。这种化学与生物之间的联系突显了理解这些结构在两个领域中的重要性。此外,benzenoid化合物的研究推动了材料科学的进步。研究人员通过修改benzenoid结构开发了具有增强性能的新材料。导电聚合物通常在电子设备中使用,往往包含benzenoid单元,以实现理想的电气特性。benzenoid化合物的多功能性使科学家能够创新并创造满足现代技术需求的材料。除了它们的实际应用之外,benzenoid化合物也是理论研究的主题。化学家利用计算方法和光谱技术探索benzenoid系统的电子结构和行为。这些研究提供了对benzenoid化合物的稳定性和反应性的见解,增强了我们对基本化学原理的理解。尽管有许多优点,但benzenoid化合物的环境影响不可忽视。一些benzenoid衍生物,如多环芳香烃(PAHs),已知具有毒性和致癌性。因此,研究人员正在积极调查减轻与这些化合物相关的风险的方法,同时仍能利用它们的有益特性。总之,术语benzenoid涵盖了一系列在化学和生物学中至关重要的化合物。它们独特的性质和多样的应用使它们成为研究和创新的重点。随着我们继续探索benzenoid化合物的潜力,平衡其益处与环境考虑至关重要。理解benzenoid化学的复杂性无疑将为未来的发现和各个科学领域的进步铺平道路。
