polymeric
简明释义
adj. 聚合的;聚合体的
英英释义
单词用法
聚合材料;聚合物材料 | |
聚合物基体 |
同义词
反义词
| 单体的 | Monomeric units are the building blocks of polymeric materials. | 单体单位是聚合材料的基本构件。 | |
| 非聚合物的 | Non-polymeric substances often have different properties compared to polymers. | 非聚合物物质通常具有与聚合物不同的性质。 |
例句
1.Shape retention is a factor in almost all articles made from polymeric materials.
形状保持性是所有聚合物材料制品共有的因素。
2.The results show that hydrophobic interaction plays an important role in polymeric reversed micelle extraction.
研究结果表明,亲油作用在聚合物反胶团萃取过程中起主导作用。
3.The preparation of polyvinylamine and its application in synthesizing polymeric dyes were described.
本文综述了聚乙烯胺的合成及其在染料中的应用。
4.Many different chemical reactions may be used to synthesize polymeric materials by step-growth polymerization.
许多不同的化学反应通过逐步聚合可用于合成聚合材料。
5.The curing cycle of polymeric composites has significant effect on its performance and economic indices.
聚合物基复合材料的固化制度是影响其性能经济指标的重要因素。
6.The results show that hydrophobic interaction plays an important role in polymeric reversed micelle extraction.
研究结果表明,亲油作用在聚合物反胶团萃取过程中起主导作用。
7.The polymeric 聚合物的 foam used in this mattress provides excellent support and comfort.
这种床垫中使用的聚合物的泡沫提供了出色的支撑和舒适感。
8.The new coating is made from a polymeric 聚合物的 material that enhances durability.
这种新涂层由一种聚合物的材料制成,可以增强耐用性。
9.Researchers are exploring polymeric 聚合物的 nanocomposites for improved electrical conductivity.
研究人员正在探索用于改善电导率的聚合物的纳米复合材料。
10.In the lab, we synthesized a new polymeric 聚合物的 compound to test its properties.
在实验室,我们合成了一种新的聚合物的化合物以测试其性质。
11.Many medical devices are made from polymeric 聚合物的 materials due to their biocompatibility.
许多医疗设备是由聚合物的材料制成的,因为它们具有生物相容性。
作文
In recent years, the field of materials science has made significant strides in understanding and utilizing various types of materials. One such category that has gained attention is polymeric (聚合物的) materials. These substances, composed of long chains of repeating molecular units, have unique properties that make them suitable for a wide range of applications. From everyday items like plastic bottles to advanced medical devices, polymeric (聚合物的) materials are integral to modern life.The versatility of polymeric (聚合物的) materials can be attributed to their ability to be engineered at the molecular level. Scientists can manipulate the length of the polymer chains, the type of monomers used, and the arrangement of these monomers to create materials with specific characteristics. For instance, polyethylene, a common polymeric (聚合物的) material, is known for its flexibility and resistance to moisture, making it ideal for packaging products. Conversely, polystyrene, another type of polymeric (聚合物的) material, is rigid and often used in insulation and disposable cutlery.Moreover, the development of new polymeric (聚合物的) materials has opened up exciting possibilities in various industries. In the automotive sector, engineers are increasingly using polymeric (聚合物的) composites to reduce vehicle weight, thereby improving fuel efficiency and reducing emissions. In the medical field, biocompatible polymeric (聚合物的) materials are being developed for use in implants and drug delivery systems, enhancing patient outcomes and safety.Another significant aspect of polymeric (聚合物的) materials is their environmental impact. With the growing concern over plastic pollution, researchers are exploring biodegradable polymeric (聚合物的) options that can break down naturally in the environment. This shift towards sustainable materials is crucial for addressing the challenges posed by traditional plastics, which can take hundreds of years to decompose.In conclusion, the study and application of polymeric (聚合物的) materials play a crucial role in advancing technology and improving quality of life. Their unique properties allow for innovation across various fields, from consumer goods to cutting-edge medical solutions. As we continue to explore the potential of polymeric (聚合物的) materials, it is essential to consider their environmental implications and strive for sustainable practices that benefit both society and the planet. The future of materials science is undoubtedly intertwined with the ongoing development of polymeric (聚合物的) substances, making this an exciting area for research and application.
近年来,材料科学领域在理解和利用各种材料方面取得了显著进展。其中一个备受关注的类别是polymeric(聚合物的)材料。这些物质由长链重复的分子单元组成,具有独特的性质,使其适用于广泛的应用。从日常物品如塑料瓶到先进的医疗设备,polymeric(聚合物的)材料在现代生活中不可或缺。polymeric(聚合物的)材料的多功能性可以归因于它们能够在分子水平上进行工程设计。科学家可以操控聚合物链的长度、所用单体的类型以及这些单体的排列,以创造具有特定特性的材料。例如,聚乙烯是一种常见的polymeric(聚合物的)材料,以其灵活性和抗潮湿性而闻名,非常适合用于包装产品。相反,聚苯乙烯是另一种polymeric(聚合物的)材料,刚性强,常用于绝缘和一次性餐具。此外,新型polymeric(聚合物的)材料的发展为各个行业带来了令人兴奋的可能性。在汽车行业,工程师越来越多地使用polymeric(聚合物的)复合材料来减轻车辆重量,从而提高燃油效率并减少排放。在医疗领域,正在开发生物相容性polymeric(聚合物的)材料,用于植入物和药物输送系统,提高患者的治疗效果和安全性。polymeric(聚合物的)材料的另一个重要方面是其对环境的影响。随着对塑料污染的日益关注,研究人员正在探索可生物降解的polymeric(聚合物的)选项,这些材料可以在环境中自然降解。这一向可持续材料的转变对于解决传统塑料带来的挑战至关重要,因为传统塑料可能需要数百年才能分解。总之,polymeric(聚合物的)材料的研究和应用在推动技术进步和改善生活质量方面发挥着关键作用。它们独特的性质使得各个领域的创新成为可能,从消费品到尖端医疗解决方案。随着我们继续探索polymeric(聚合物的)材料的潜力,有必要考虑其环境影响,并努力实现有利于社会和地球的可持续实践。材料科学的未来无疑与polymeric(聚合物的)物质的持续发展息息相关,这使得这一领域成为研究和应用的激动人心的领域。
