chain compound

简明释义

链化合物

英英释义

例句

1.The study of chain compounds 链化合物 is crucial for understanding polymer synthesis.

研究链化合物 chain compounds 对于理解聚合物合成至关重要。

2.A chain compound 链化合物 can be saturated or unsaturated based on the presence of double bonds.

根据双键的存在，链化合物 chain compound 可以是饱和或不饱和的。

3.In organic chemistry, a chain compound 链化合物 refers to a molecule that consists of a linear arrangement of atoms.

在有机化学中，链化合物 chain compound 指的是由原子线性排列组成的分子。

4.Researchers are exploring the properties of chain compounds 链化合物 to develop new materials.

研究人员正在探索链化合物 chain compounds 的特性，以开发新材料。

5.Many plastics are made from chain compounds 链化合物 that can be easily molded into various shapes.

许多塑料是由可以轻易成型为各种形状的链化合物 chain compounds 制成的。

作文

In the world of chemistry, the term chain compound refers to a specific type of chemical compound that consists of a series of atoms connected in a linear or branched formation. These compounds are often characterized by their long carbon chains, which can vary in length and complexity. A common example of a chain compound is hydrocarbons, where hydrogen atoms are bonded to carbon atoms in a continuous chain. Understanding chain compounds is essential for students and professionals in the field of chemistry, as they play a crucial role in the development of various materials and substances used in everyday life.The significance of chain compounds extends beyond the laboratory. In fact, they are foundational to the production of fuels, plastics, and even pharmaceuticals. For instance, when we consider gasoline, it is primarily composed of a mixture of chain compounds known as alkanes. These alkanes are saturated hydrocarbons, meaning they contain single bonds between carbon atoms, forming a stable structure that is ideal for combustion.Moreover, the study of chain compounds also involves exploring their properties and reactions. The reactivity of these compounds can be influenced by the length of the carbon chain, the presence of functional groups, and the overall molecular structure. For example, shorter chain compounds tend to be gases at room temperature, while longer ones can be liquids or solids. This variation in physical state is important for applications in various industries, including energy and manufacturing.Additionally, chain compounds can exhibit isomerism, where molecules with the same molecular formula have different structural arrangements. This phenomenon is particularly interesting because it leads to compounds with distinct chemical and physical properties. Understanding isomerism in chain compounds is vital for chemists who aim to synthesize specific compounds for targeted applications.In recent years, the exploration of chain compounds has expanded into the realm of biochemistry, where researchers study naturally occurring chain compounds like fatty acids and amino acids. These biological chain compounds are essential for life, as they form the building blocks of lipids and proteins, respectively. The intricate relationships between these compounds and their functions in living organisms highlight the importance of understanding chain compounds not only in synthetic chemistry but also in biological systems.In conclusion, chain compounds are a fundamental aspect of chemistry that impacts a wide range of fields. From energy production to biological processes, the study of these compounds provides insights into the molecular world around us. As we continue to advance our knowledge and technologies, the role of chain compounds will remain critical in addressing challenges such as sustainable energy and healthcare innovations. By deepening our understanding of chain compounds, we pave the way for future discoveries that can benefit society as a whole.

在化学的世界中，术语链状化合物指的是由一系列原子以线性或分支形式连接而成的特定类型的化合物。这些化合物通常以其长碳链为特征，这些碳链的长度和复杂性可以有所不同。链状化合物的一个常见例子是烃，其中氢原子与碳原子以连续链的方式结合。理解链状化合物对化学领域的学生和专业人士至关重要，因为它们在日常生活中各种材料和物质的发展中发挥着关键作用。链状化合物的重要性超越了实验室。实际上，它们是燃料、塑料甚至制药生产的基础。例如，当我们考虑汽油时，它主要由一系列称为烷烃的链状化合物混合而成。这些烷烃是饱和烃，意味着它们在碳原子之间含有单键，形成一种稳定的结构，适合燃烧。此外，研究链状化合物还涉及探索它们的性质和反应。这些化合物的反应性可能受到碳链长度、功能团的存在以及整体分子结构的影响。例如，较短的链状化合物在室温下往往是气体，而较长的则可以是液体或固体。这种物理状态的变化对于能源和制造等各个行业的应用至关重要。另外，链状化合物可以表现出异构现象，即具有相同分子式的分子具有不同的结构排列。这种现象特别有趣，因为它导致具有不同化学和物理性质的化合物。在合成特定用途的化合物时，理解链状化合物中的异构现象对化学家来说至关重要。近年来，对链状化合物的研究扩展到了生物化学领域，研究人员研究天然存在的链状化合物，如脂肪酸和氨基酸。这些生物链状化合物对于生命至关重要，因为它们构成了脂质和蛋白质的基本构件。这些化合物及其在生物体内的功能之间的复杂关系突显了理解链状化合物的重要性，不仅在合成化学中，也在生物系统中。总之，链状化合物是化学的一个基本方面，影响着广泛的领域。从能源生产到生物过程，这些化合物的研究提供了对我们周围分子世界的深入见解。随着我们不断推进知识和技术，链状化合物的角色将继续在应对可持续能源和医疗创新等挑战中发挥关键作用。通过深化对链状化合物的理解，我们为未来的发现铺平了道路，这些发现可以惠及整个社会。