Study on Biodegradability and Mechanism of Cyanoethylated Waste Paper

Q3 Environmental Science
Chunhong Zhang, Qin Li
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引用次数: 0

Abstract

With white pollution caused by petroleum plastics becoming an environmental issue of global concern, biodegradable plastics have become a research hotspot, and biodegradable materials made from plants have been attracting attention. Based on previous studies, this paper studied the biodegradability of thermoplastic cyanoethylated waste paper (CWP) by microbial experiment, and preliminarily explored the degradation mechanism. The results showed that: (1) the biodegradability of CWP was better than that of waste paper, and the higher the degree of modification, the better the biodegradability of CWP; under the action of Trichoderma reesei, the degradation rate of CWP containing 20.79% nitrogen was about 24% after 144 h (hours) of degradation; (2) The degradation rate of CWP was about 45% after 144 hours degradation by microbial complex bacteria, which was mainly due to the synergistic effect of cellulose degrading enzymes secreted by microbial degrading bacteria, which greatly improved the degradation rate of CWP. (3) The improvement of biodegradability of CWP was mainly due to the change of the morphology of the fibers by cyanoethylation reaction, which increased the contact surface and destroyed the crystal structure of the waste paper fibers. The increase of the amorphous region and the distance between the crystal planes was more conducive to the cellulase entering into the CWP, thus improving the degradation rate. (4) Structural analysis of CWP before and after degradation showed that microbial degradation bacteria destroyed C≡N bond and formed hydrocarbon bond, and further destroyed the crystal structure of CWP without changing the crystal form of the fiber.
氰乙基废纸的生物降解性及其机理研究
随着石油塑料造成的白色污染成为全球关注的环境问题,生物降解塑料成为研究热点,植物可降解材料一直备受关注。本文在前人研究的基础上,通过微生物实验对热塑性氰乙基化废纸(CWP)的生物降解性进行了研究,并初步探讨了其降解机理。结果表明:(1)CWP的生物降解性优于废纸,且改性程度越高,CWP的生物降解性越好;在里氏木霉作用下,含氮20.79%的CWP在降解144 h后的降解率约为24%;(2)微生物复合菌对CWP的降解时间为144 h,降解率约为45%,这主要是由于微生物降解菌分泌的纤维素降解酶的协同作用,大大提高了CWP的降解率。(3) CWP生物降解性的提高主要是由于氰乙基化反应改变了纤维的形态,增加了废纸纤维的接触面,破坏了废纸纤维的晶体结构。无定形区和晶面间距的增加更有利于纤维素酶进入CWP,从而提高降解速率。(4)降解前后的CWP结构分析表明,微生物降解菌破坏了C≡N键,形成碳氢键,在不改变纤维晶型的情况下进一步破坏了CWP的晶体结构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Strategic Planning for Energy and the Environment
Strategic Planning for Energy and the Environment Environmental Science-Environmental Science (all)
CiteScore
1.50
自引率
0.00%
发文量
25
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