Nanotechnology in Plastic Degradation

R. Chandran, Benjamin Isaac Thomson, A. J. Natishah, Jennita Mary, V. Nachiyar
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引用次数: 1

Abstract

Plastics pose a huge threat to the environment. Plastic accumulation in the land and the seas is now the world’s most terrorising problem, mainly because of its non-degrading character. Plastic degradation has always been a next to impossible concept in the field of science, but nanotechnology provides a revolutionary and modern way to solve the problem of plastic accumulation in the environment. One of the great advantages of nanoparticles is that we can increase and decrease the rate of biodegradation depending on our needs. Nanoparticles enhance the polythene degradation capacity of the microorganisms by altering their metabolic cycles. Numerous studies showed conclusively that the incorporation of nanotechnology enhances the ability of microorganisms to degrade polythene materials. Even though bio degradable plastics are nowadays produced in large quantities to substitute polythene materials, they fail to match the brittleness of plastics. Biodegradable plastics have poor thermal, mechanical and low gas barrier qualities, which are their main drawbacks. To overcome this, nanoparticles are incorporated into the biopolymers. If an appropriate balance between nanotechnology, microbiology and biotechnology is found, plastic degradation can be done economically and feasibly in all the areas.
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纳米技术在塑料降解中的应用
塑料对环境构成巨大威胁。陆地和海洋中的塑料堆积现在是世界上最可怕的问题,主要是因为它的非降解特性。塑料降解在科学领域一直是一个近乎不可能的概念,但纳米技术为解决塑料在环境中的积累问题提供了一种革命性的现代方法。纳米粒子的一大优点是我们可以根据自己的需要来提高或降低生物降解的速度。纳米颗粒通过改变微生物的代谢循环来增强其降解聚乙烯的能力。大量研究表明,纳米技术的加入增强了微生物降解聚乙烯材料的能力。尽管生物可降解塑料现在被大量生产以取代聚乙烯材料,但它们无法与塑料的脆性相匹配。可生物降解塑料的主要缺点是热、机械和气体阻隔性差。为了克服这个问题,纳米粒子被加入到生物聚合物中。如果在纳米技术、微生物学和生物技术之间找到适当的平衡,塑料降解可以在所有领域进行经济和可行的。
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