living polymer

简明释义

活性聚合物

英英释义

例句

1.Applications of living polymer 活性聚合物 include self-healing materials and smart coatings.

活性聚合物的应用包括自愈材料和智能涂层。

2.In the lab, we can manipulate the properties of living polymer 活性聚合物 to create tailored materials.

在实验室中，我们可以操控活性聚合物的性质，以创造定制材料。

3.The development of living polymer 活性聚合物 technology has revolutionized the field of materials science.

活性聚合物技术的发展彻底改变了材料科学领域。

4.Researchers are exploring the use of living polymer 活性聚合物 systems for drug delivery applications.

研究人员正在探索将活性聚合物系统用于药物递送应用。

5.The ability to control the growth of living polymer 活性聚合物 opens new avenues in synthetic biology.

控制活性聚合物生长的能力为合成生物学开辟了新途径。

作文

In the world of materials science, the term living polymer refers to a unique class of polymers that possess the ability to grow and change in response to environmental conditions. Unlike traditional polymers, which are static and fixed in structure once formed, living polymers can undergo continuous chain growth, allowing for a dynamic range of properties and functionalities. This characteristic makes them particularly valuable in various applications, from biomedical devices to advanced coatings. The concept of living polymers emerged from the field of controlled/living radical polymerization, which revolutionized how chemists approach polymer synthesis. In this process, the polymer chains are able to maintain their active sites throughout the reaction, leading to well-defined molecular weights and narrow polydispersity. This level of control enables scientists to tailor the properties of the resulting materials for specific applications, making living polymers a focal point in modern polymer chemistry. One of the most exciting aspects of living polymers is their potential in biomedical applications. For instance, researchers are exploring the use of living polymers to create drug delivery systems that can respond to physiological changes in the body. By designing polymers that can release therapeutic agents in a controlled manner, it is possible to enhance the efficacy of treatments while minimizing side effects. Moreover, living polymers can be engineered to mimic natural biological processes, paving the way for innovative solutions in tissue engineering and regenerative medicine. Another area where living polymers show promise is in the development of smart materials. These materials can respond to external stimuli such as temperature, pH, or light, enabling them to change their shape, color, or mechanical properties on demand. This adaptability opens up new possibilities in fields like soft robotics, where living polymers could be used to create flexible, responsive structures that can adapt to their environment. Despite their advantages, the use of living polymers also presents challenges. The complexity of their synthesis and the need for precise control over polymerization conditions require advanced techniques and equipment. Additionally, ensuring the stability and reproducibility of living polymers in practical applications remains an ongoing area of research. In conclusion, living polymers represent a fascinating intersection of chemistry, biology, and engineering. Their ability to grow, adapt, and respond to their environment positions them as key players in the future of material science. As researchers continue to unlock the potential of living polymers, we can expect to see groundbreaking advancements in various fields, ultimately improving our quality of life and addressing some of the world's most pressing challenges.

在材料科学的世界中，术语living polymer指的是一种独特的聚合物类别，这些聚合物具有根据环境条件生长和变化的能力。与传统聚合物不同，后者在形成后是静态且结构固定的，living polymers可以经历连续的链增长，从而实现动态的性能和功能范围。这一特性使它们在生物医学设备到先进涂层等各种应用中尤为宝贵。living polymers的概念源自受控/活性自由基聚合领域，这一概念彻底改变了化学家们对聚合物合成的看法。在这一过程中，聚合物链能够在反应过程中保持其活性位点，从而导致分子量的良好定义和窄的分散度。这种控制水平使科学家能够为特定应用量身定制所得到材料的性能，使得living polymers成为现代聚合物化学的焦点。living polymers最令人兴奋的方面之一是它们在生物医学应用中的潜力。例如，研究人员正在探索使用living polymers创建能够响应身体生理变化的药物递送系统。通过设计能够以可控方式释放治疗剂的聚合物，可以提高治疗效果，同时最小化副作用。此外，living polymers可以被设计为模拟自然生物过程，为组织工程和再生医学中的创新解决方案铺平道路。living polymers另一个展现潜力的领域是智能材料的发展。这些材料能够响应温度、pH或光等外部刺激，使其能够按需改变形状、颜色或机械性能。这种适应性为软机器人等领域开辟了新的可能性，在这些领域中，living polymers可以用于创建灵活、响应环境变化的结构。尽管有其优势，living polymers的使用也面临挑战。其合成的复杂性以及对聚合条件精确控制的需求需要先进的技术和设备。此外，确保living polymers在实际应用中的稳定性和重现性仍然是一个持续的研究领域。总之，living polymers代表了化学、生物学和工程学的迷人交汇点。它们生长、适应和响应环境的能力使其在材料科学的未来中占据关键地位。随着研究人员继续挖掘living polymers的潜力，我们可以期待在各个领域取得突破性进展，最终改善我们的生活质量，并应对一些世界上最紧迫的挑战。