polymerism

简明释义

英[/ˈpɒlɪmərɪzəm/]美[/ˈpɒlɪmərɪzəm/]

n. 聚合性，[高分子] 聚合现象

英英释义

单词用法

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反义词

例句

1.This article analysis the principle of the benzyl chloride polymerism and it' s cause and introduces the effect of composite stabilizer W102 in preventing benzyl chloride polymerization.

分析了氯化苄的聚合机理及原因，介绍了复合稳定剂W102在防止氯化苄聚合中的使用效果。

2.This article analysis the principle of the benzyl chloride polymerism and it' s cause and introduces the effect of composite stabilizer W102 in preventing benzyl chloride polymerization.

分析了氯化苄的聚合机理及原因，介绍了复合稳定剂W102在防止氯化苄聚合中的使用效果。

3.The concept of polymerism is often applied in biology to explain how proteins are formed.

在生物学中，聚合现象的概念常用于解释蛋白质是如何形成的。

4.The study of polymerism is crucial for developing new materials in the field of nanotechnology.

对聚合现象的研究对纳米技术领域新材料的开发至关重要。

5.Researchers are exploring the role of polymerism in the creation of biodegradable materials.

研究人员正在探索聚合现象在可生物降解材料创建中的作用。

6.Understanding polymerism can help scientists create more efficient plastics.

理解聚合现象可以帮助科学家创造更高效的塑料。

7.In chemistry, polymerism refers to the phenomenon where small molecules combine to form larger structures.

在化学中，聚合现象指的是小分子结合形成更大结构的现象。

作文

Polymerism is a fascinating concept that plays a crucial role in the fields of chemistry and biology. At its core, polymerism (聚合现象) refers to the phenomenon where small molecules, known as monomers, combine to form larger structures called polymers. This process is not only fundamental to the creation of various materials but also essential for the understanding of biological macromolecules such as proteins, nucleic acids, and carbohydrates.To comprehend polymerism (聚合现象) fully, it is important to explore how these polymers are formed. The process begins with the linking of monomers through chemical reactions. These reactions can occur in several ways, including addition polymerization and condensation polymerization. In addition polymerization, unsaturated monomers react to form long chains, while in condensation polymerization, monomers join together with the loss of a small molecule, often water. Both processes highlight the versatility and complexity of polymerism (聚合现象) in creating diverse chemical compounds.One of the most significant implications of polymerism (聚合现象) is found in everyday materials. For instance, synthetic polymers such as polyethylene and polystyrene have revolutionized packaging and manufacturing. These materials exhibit unique properties such as flexibility, durability, and resistance to moisture, which make them ideal for a wide range of applications. Additionally, natural polymers like cellulose and proteins are integral to life itself. Cellulose provides structural support in plants, while proteins serve as enzymes, hormones, and antibodies in living organisms.Moreover, polymerism (聚合现象) is not limited to just physical materials; it extends into the realm of nanotechnology and biomedical applications. Researchers are exploring how polymers can be used to design drug delivery systems that target specific cells in the body, enhancing the effectiveness of treatments while minimizing side effects. This innovative approach is a direct result of understanding the principles of polymerism (聚合现象) and how to manipulate polymer structures at the molecular level.In conclusion, polymerism (聚合现象) is a key concept that bridges the gap between chemistry and biology, influencing both our understanding of the natural world and the development of new technologies. As we continue to study and apply the principles of polymerism (聚合现象), we open doors to new possibilities in material science, medicine, and beyond. Embracing this knowledge not only enhances our scientific literacy but also empowers us to innovate solutions to some of the world's most pressing challenges.