low temperature polymerization

简明释义

低温聚合

英英释义

例句

1.The research team focused on the effects of low temperature polymerization 低温聚合 to enhance the material properties of biodegradable plastics.

研究团队专注于低温聚合 low temperature polymerization 对生物可降解塑料材料特性的影响。

2.The benefits of low temperature polymerization 低温聚合 include reduced energy consumption during the manufacturing process.

使用低温聚合 low temperature polymerization的好处包括在制造过程中减少能源消耗。

3.The application of low temperature polymerization 低温聚合 in the textile industry has led to the development of new, innovative fabrics.

在纺织行业中应用低温聚合 low temperature polymerization已经导致新型创新面料的开发。

4.Researchers are exploring low temperature polymerization 低温聚合 as a method to create more environmentally friendly adhesives.

研究人员正在探索低温聚合 low temperature polymerization作为一种制造更环保粘合剂的方法。

5.Using low temperature polymerization 低温聚合, we were able to produce a more stable polymer that can withstand higher pressures.

通过使用低温聚合 low temperature polymerization，我们能够生产出一种更稳定的聚合物，能够承受更高的压力。

作文

Low temperature polymerization is a fascinating process that has garnered significant attention in the field of materials science and chemistry. This technique involves the synthesis of polymers at temperatures lower than those typically used in conventional polymerization methods. The primary advantage of low temperature polymerization (低温聚合) lies in its ability to produce high-quality polymers with unique properties, which can be particularly beneficial for various industrial applications.One of the key benefits of low temperature polymerization (低温聚合) is the reduction of thermal degradation during the polymerization process. At elevated temperatures, many monomers and growing polymer chains can undergo side reactions, leading to unwanted by-products that can compromise the integrity and performance of the final polymer product. By conducting the polymerization at lower temperatures, these undesirable reactions can be minimized, resulting in purer and more stable polymers.Moreover, low temperature polymerization (低温聚合) allows for better control over the molecular weight and distribution of the resulting polymers. This is crucial for applications where specific mechanical properties are required. For instance, in the production of elastomers or thermoplastics, having a precise molecular weight can significantly influence the elasticity, strength, and durability of the material. Researchers have found that by carefully adjusting the temperature during the polymerization process, they can tailor the properties of the polymer to meet specific needs.Additionally, low temperature polymerization (低温聚合) opens up new avenues for the synthesis of novel materials. For example, it enables the incorporation of sensitive functional groups into the polymer backbone without risking their degradation. This is particularly important in fields such as biomedical engineering, where polymers are often required to have specific biochemical properties for drug delivery systems or tissue engineering scaffolds. By utilizing low temperature polymerization (低温聚合), scientists can create advanced materials that exhibit enhanced biocompatibility and functionality.Another aspect worth noting is the environmental impact of low temperature polymerization (低温聚合). Traditional polymerization processes often require the use of high temperatures and pressures, which can consume a considerable amount of energy and contribute to greenhouse gas emissions. In contrast, low temperature polymerization (低温聚合) can be conducted under milder conditions, potentially leading to a more sustainable approach to polymer production. This aligns well with the growing emphasis on green chemistry and the development of eco-friendly manufacturing practices.In conclusion, low temperature polymerization (低温聚合) represents a significant advancement in polymer chemistry, offering numerous advantages such as improved polymer quality, better control over properties, the ability to synthesize novel materials, and reduced environmental impact. As researchers continue to explore this technique, we can expect to see exciting developments in the creation of next-generation materials that will have a profound impact on various industries, from packaging to healthcare. The ongoing research in this area holds great promise for the future of material science, paving the way for innovative solutions to meet the challenges of modern society.

低温聚合是一种迷人的过程，在材料科学和化学领域引起了广泛关注。这种技术涉及在低于传统聚合方法通常使用的温度下合成聚合物。低温聚合的主要优势在于其能够生产具有独特性质的高质量聚合物，这对于各种工业应用特别有益。低温聚合的一个关键好处是减少聚合过程中热降解的发生。在高温下，许多单体和生长的聚合物链可能会发生副反应，导致不必要的副产物，这可能会影响最终聚合物产品的完整性和性能。通过在较低温度下进行聚合，可以最小化这些不良反应，从而得到更纯净、更稳定的聚合物。此外，低温聚合还允许更好地控制所产生聚合物的分子量和分布。这对于需要特定机械性能的应用至关重要。例如，在弹性体或热塑性塑料的生产中，具有精确分子量可以显著影响材料的弹性、强度和耐用性。研究人员发现，通过仔细调整聚合过程中的温度，可以定制聚合物的性能以满足特定需求。另外，低温聚合为新型材料的合成开辟了新的途径。例如，它使得能够将敏感的功能基团融入聚合物主链，而不会冒着降解的风险。这在生物医学工程等领域尤为重要，因为这些领域的聚合物通常需要具有特定的生化性质，以用于药物传递系统或组织工程支架。通过利用低温聚合，科学家们可以创造出具有增强生物相容性和功能性的先进材料。另一个值得注意的方面是低温聚合对环境的影响。传统的聚合过程通常需要高温和高压，这可能消耗大量能源并导致温室气体排放。相比之下，低温聚合可以在较温和的条件下进行，可能导致更可持续的聚合物生产方法。这与日益强调绿色化学和生态友好制造实践的趋势相符。总之，低温聚合代表了聚合物化学的一项重大进展，提供了许多优势，如改善聚合物质量、更好的性能控制、合成新型材料的能力以及减少环境影响。随着研究人员继续探索这一技术，我们可以期待在创建下一代材料方面看到令人兴奋的发展，这将对各个行业产生深远的影响，从包装到医疗保健。该领域的持续研究对材料科学的未来充满希望，为应对现代社会的挑战铺平了道路。