trimethylene
简明释义
英[traɪˈmeθɪliːn]美[traɪˈmeθɪlɪn]
n. 三甲烯;环丙烷(等于 cyclopropane)
英英释义
单词用法
三亚基甘油 | |
三亚基氧化物 | |
三亚基链 | |
三亚基桥 |
同义词
反义词
四亚甲基 | 四亚甲基常用于聚合物的合成。 | ||
五亚甲基 | Pentamethylene can be found in certain chemical reactions as a precursor. | 五亚甲基可以在某些化学反应中作为前体。 |
例句
1.The changes of intrinsic viscosity and end carboxyl group content with temperature and time were studied for poly(trimethylene terephthalate)(PTT), PET and CDP.
研究了聚对苯二甲酸丙二醇酯(PTT) ,PET ,C DP在不同温度和时间下的特性粘数和端羧基含量的变化。
2.The changes of intrinsic viscosity and end carboxyl group content with temperature and time were studied for poly(trimethylene terephthalate)(PTT), PET and CDP.
研究了聚对苯二甲酸丙二醇酯(PTT) ,PET ,C DP在不同温度和时间下的特性粘数和端羧基含量的变化。
3.The chemical structure of trimethylene 三亚甲基 is often used in organic synthesis.
三亚甲基的化学结构常用于有机合成。
4.Researchers found that trimethylene 三亚甲基 can be a useful intermediate in the production of various polymers.
研究人员发现三亚甲基可以作为多种聚合物生产中的有用中间体。
5.In the laboratory, we synthesized a compound using trimethylene 三亚甲基 as a starting material.
在实验室中,我们以三亚甲基作为起始材料合成了一种化合物。
6.The stability of trimethylene 三亚甲基 under certain conditions is crucial for its applications.
三亚甲基在某些条件下的稳定性对其应用至关重要。
7.When heated, trimethylene 三亚甲基 can undergo rearrangement to form more stable compounds.
当加热时,三亚甲基可以发生重排形成更稳定的化合物。
作文
In the world of organic chemistry, understanding the structure and properties of various compounds is essential for both students and professionals. One such compound that often comes up in discussions is trimethylene. This term refers to a specific hydrocarbon chain that consists of three carbon atoms connected by single bonds, with the molecular formula C3H6. The significance of trimethylene lies not only in its simple structure but also in its reactivity and applications in various chemical processes. The structure of trimethylene can be visualized as a straight chain of three carbon atoms, each bonded to sufficient hydrogen atoms to satisfy the tetravalency of carbon. This results in a linear arrangement that can participate in various chemical reactions. For instance, trimethylene can undergo polymerization, a process where small molecules combine to form larger, more complex structures. This property makes it an interesting compound in the field of materials science, where it can be used to create polymers with desirable characteristics. Moreover, trimethylene serves as a building block for more complex organic molecules. In synthetic organic chemistry, it can be utilized to construct larger frameworks through various reactions, such as substitution and addition reactions. These reactions are fundamental in creating pharmaceuticals, agrochemicals, and other industrial products. Understanding how trimethylene interacts with other chemicals allows chemists to design new compounds with specific functionalities, which can lead to innovations in drug development and material production. One of the fascinating aspects of trimethylene is its role in the formation of cyclic compounds. When subjected to certain conditions, trimethylene can form cyclic structures known as cyclopropanes. These compounds are characterized by their unique three-membered ring, which exhibits significant strain due to the angular configuration of the carbon atoms. Cyclopropanes derived from trimethylene are of great interest because they possess unique chemical properties that can be exploited in various chemical reactions. For example, they can serve as intermediates in the synthesis of larger, more complex organic molecules. In addition to its theoretical significance, trimethylene also has practical applications in everyday life. It can be found in some industrial solvents and is involved in the production of various chemicals used in manufacturing. Its derivatives are utilized in the creation of plastics, resins, and other materials that form the backbone of countless products we use daily. Understanding trimethylene and its derivatives helps industries optimize their processes and develop more efficient materials. In conclusion, trimethylene is a fundamental compound in organic chemistry that serves as a critical building block for many reactions and applications. Its simple structure belies its importance in the synthesis of complex molecules and materials. As students and professionals delve deeper into the world of chemistry, grasping the implications of trimethylene will enhance their understanding of organic reactions and material science. Whether it's in the lab or industry, the knowledge of compounds like trimethylene is invaluable for innovation and progress in the chemical sciences.
在有机化学的世界中,理解各种化合物的结构和性质对于学生和专业人士来说至关重要。其中一个经常出现在讨论中的化合物是trimethylene。这个术语指的是一种特定的烃链,由三个碳原子通过单键连接而成,分子式为C3H6。trimethylene的重要性不仅在于它简单的结构,还在于它的反应性和在各种化学过程中的应用。 trimethylene的结构可以被视为一条直链,由三个碳原子组成,每个碳原子与足够的氢原子结合,以满足碳的四价性。这导致了一种线性排列,可以参与各种化学反应。例如,trimethylene可以发生聚合反应,这是一种小分子结合形成更大、更复杂结构的过程。这一特性使其在材料科学领域中成为一种有趣的化合物,可以用来创造具有理想特性的聚合物。 此外,trimethylene作为更复杂有机分子的构建块。在合成有机化学中,它可以通过各种反应,如取代反应和加成反应,用于构建更大的框架。这些反应在制药、农药和其他工业产品的生产中至关重要。了解trimethylene如何与其他化学物质相互作用,使化学家能够设计具有特定功能的新化合物,从而推动药物开发和材料生产的创新。 trimethylene的一个迷人之处在于它在环状化合物形成中的作用。在某些条件下,trimethylene可以形成称为环丙烷的环状结构。这些化合物的特点是它们独特的三元环,由于碳原子的角度构型而表现出显著的应变。由trimethylene衍生出的环丙烷因其独特的化学性质而受到极大关注,这些性质可以在各种化学反应中被利用。例如,它们可以作为合成更大、更复杂有机分子的中间体。 除了理论上的重要性外,trimethylene在日常生活中也具有实际应用。它可以在一些工业溶剂中找到,并参与各种化学品的生产,这些化学品用于制造。其衍生物被用于塑料、树脂和其他材料的制造,这些材料构成了我们每天使用的无数产品的骨干。理解trimethylene及其衍生物有助于工业优化其过程并开发更高效的材料。 总之,trimethylene是有机化学中的一种基本化合物,作为许多反应和应用的关键构建块。它简单的结构掩盖了它在复杂分子和材料合成中的重要性。随着学生和专业人士深入探索化学世界,掌握trimethylene的含义将增强他们对有机反应和材料科学的理解。无论是在实验室还是工业中,对像trimethylene这样的化合物的知识对于化学科学的创新和进步都是无价的。
文章标题:trimethylene的意思是什么
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