phenylene

简明释义

英[ˈfenɪliːn]美[ˈfenəˌlin;ˈfinəˌlin]

n. 亚苯基

英英释义

单词用法

同义词

反义词

例句

1.Poly(phenylene sulfide) (PPS) is a high-performance engineering plastics with many excellent properties.

聚苯硫醚（PPS）是一种高性能的特种工程塑料，具有各种优异的性能。

2.The influence of water content on the quality of the product in the synthesis of Poly (phenylene sulfide) (PPS) with high purity was studied.

研究了在高纯聚苯硫醚(PPS)树脂合成中，水量的变化对产品质量的影响。

3.The enzyme labelled antibodies are made from purified rabbit antibodies against human CEA and AFP and linked with peroxidase using O-phenylene diamine as a substrate.

用已纯化兔抗人CEA和AFP的抗体分别与辣根过氧化物酶结合制得酶标抗体。

4.The poly (p phenylene borane) and poly (m phenylene borane) are synthesized by the modified organometallic route.

用改进的有机金属路线合成了聚对亚苯基硼和聚间亚苯基硼。

5.Polyp-phenylene benzobisthiazole(PBO), a new high-performance organic fiber, is introduced in this paper.

介绍了一种新型高性能有机纤维聚对苯撑苯并双恶唑简称PBO。

6.The maintaining requirements of polyamide fiber and poly-phenylene terephthalamide materials in warehouse were analyzed by the trial of relative humidity effecting degradability of them in the paper.

通过相对湿度对锦纶和芳纶材料降解性能影响的试验，分析了两种材料在仓库的保管条件，提出了更有利于材料贮存的温湿度条件的建议。

7.Basing on first-principles and elastic scattering Greens function theory, we study the electronic transport property of oligomeric phenylene ethynylene molecular devices.

利用弹性散射格林函数方法，研究了低聚次苯基乙炔分子器件的电输运性质，并分析了水环境对分子器件电输运性质的影响。

8.The compound contains a chain of phenylene 苯基 groups that enhance its conductivity.

该化合物包含一系列的phenylene 苯基 基团，这增强了它的导电性。

9.In the synthesis of polymers, phenylene 苯基 units are often used to improve thermal stability.

在聚合物的合成中，phenylene 苯基 单元常用于提高热稳定性。

10.The research focused on the properties of phenylene 苯基 derivatives in organic electronics.

研究集中在phenylene 苯基 衍生物在有机电子学中的特性上。

11.Aromatic compounds like phenylene 苯基 are crucial in developing new materials.

像phenylene 苯基这样的芳香族化合物在开发新材料中至关重要。

12.The stability of phenylene 苯基 rings makes them ideal for various chemical applications.

由于phenylene 苯基 环的稳定性，使其在各种化学应用中非常理想。

作文

The world of chemistry is filled with complex structures and fascinating compounds, one of which is phenylene. This term refers to a group of organic compounds that contain a benzene ring structure. Understanding phenylene is crucial for anyone interested in organic chemistry or materials science. The basic unit of phenylene is derived from the benzene molecule, which is composed of six carbon atoms arranged in a hexagonal ring, with alternating double bonds. When we talk about phenylene, we often refer to its derivatives, such as diphenylene, which consists of two benzene rings connected by a single bond. These compounds exhibit unique properties that make them valuable in various applications, including the production of polymers and dyes. One of the most interesting aspects of phenylene is its role in the development of high-performance materials. For instance, poly(phenylene sulfide) (PPS) is a polymer that incorporates phenylene units in its structure, resulting in a material that is resistant to heat and chemicals. This makes PPS suitable for use in automotive and aerospace industries where durability is essential. Additionally, phenylene derivatives are often used in the synthesis of liquid crystals, which are crucial for modern display technologies, including televisions and smartphones. Moreover, the study of phenylene compounds extends beyond industrial applications. Researchers are exploring their potential in the field of nanotechnology. For example, phenylene oligomers can be used to create nanoscale materials with specific electronic properties. These materials could lead to advancements in electronics, such as faster and more efficient transistors. In environmental science, the significance of phenylene compounds cannot be overlooked. Some phenylene derivatives are known to be persistent in the environment and can pose risks to ecosystems. Understanding their behavior and degradation pathways is essential for developing strategies to mitigate their impact. Thus, studying phenylene not only enhances our knowledge of chemistry but also informs environmental policies and practices. In summary, phenylene is a fundamental concept in organic chemistry that has far-reaching implications across various fields. Its unique structure and properties enable the development of advanced materials and technologies, while also posing environmental challenges. As we continue to explore the potential of phenylene compounds, it becomes increasingly important to balance innovation with sustainability. The journey of understanding phenylene is ongoing, and it promises to unveil new possibilities that can shape our future in science and technology.

化学的世界充满了复杂的结构和迷人的化合物，其中之一就是phenylene。这个术语指的是一组包含苯环结构的有机化合物。理解phenylene对任何对有机化学或材料科学感兴趣的人来说都是至关重要的。phenylene的基本单元源于苯分子，苯分子由六个碳原子以六边形环状排列，具有交替的双键。当我们谈论phenylene时，我们通常指的是它的衍生物，例如联苯，它由两个通过单键连接的苯环组成。这些化合物表现出独特的性质，使它们在各种应用中具有价值，包括聚合物和染料的生产。 phenylene最有趣的方面之一是它在高性能材料开发中的作用。例如，聚苯硫醚（PPS）是一种在其结构中包含phenylene单元的聚合物，导致这种材料耐热和耐化学性。这使得PPS适用于汽车和航空航天工业，其中耐用性至关重要。此外，phenylene衍生物通常用于液晶的合成，这对于现代显示技术（包括电视和智能手机）至关重要。 此外，phenylene化合物的研究不仅限于工业应用。研究人员正在探索它们在纳米技术领域的潜力。例如，phenylene寡聚物可用于创建具有特定电子特性的纳米级材料。这些材料可能会导致电子学的进步，例如更快、更高效的晶体管。 在环境科学中，phenylene化合物的重要性不容忽视。一些phenylene衍生物已知在环境中持久存在，并可能对生态系统构成风险。理解它们的行为和降解途径对于制定减轻其影响的策略至关重要。因此，研究phenylene不仅增强了我们对化学的理解，也为环境政策和实践提供了信息。 总之，phenylene是有机化学中的一个基本概念，在各个领域都有深远的影响。其独特的结构和性质使得先进材料和技术的发展成为可能，同时也带来了环境挑战。随着我们继续探索phenylene化合物的潜力，平衡创新与可持续性变得越来越重要。理解phenylene的旅程仍在继续，它承诺揭示可以塑造我们科学和技术未来的新可能性。