{"title":"非生物处理改性硬脂酸钴填充聚丙烯薄膜的性能及生物降解模拟","authors":"Sunil Sable, Sanjeev Ahuja","doi":"10.1007/s13726-023-01228-y","DOIUrl":null,"url":null,"abstract":"<div><p>The present work studies the effects of abiotic pretreatment on the properties and biodegradability of the modified cobalt stearate pro-degradant filled polypropylene films, and on the eco-toxicity of their biodegraded products. Before abiotic pretreatment, their processability was confirmed by rheological studies. After abiotic pretreatment, FTIR revealed their carbonyl index increased on increasing the pro-degradant loading. Their GPC results showed significant decrease in molecular weight, thus indicating chain scission and intermediate formation. Their thermal stability also reduced as demonstrated by TGA. Their DSC and XRD analyses showed decreased crystallinity thereby indicating increased biodegradability. Their biodegradation was measured following ASTM D 5338, which showed a significant increase with abiotic pretreatment and the same was substantiated by GPC. The biodegradation kinetics followed Komilis model which showed that the degradation rate reached a maximum of 0.407–0.730% per day at 15–25th day. Readily hydrolysable carbon and its hydrolysis rate constant substantially enhanced with modified pro-degradant content. High readily hydrolyzable carbon rate constant caused the occurrence of a prominent growth phase. SEM also confirmed that the surface morphology of each film became increasingly rougher subsequent to both abiotic and biotic treatments, and with increasing pro-degradant loading. The eco-toxicity tests confirmed the nontoxicity of biodegraded products. The work thus illustrated that the films can have useful packaging applications.</p><h3>Graphical abstract</h3>\n <div><figure><div><div><picture><source><img></source></picture></div></div></figure></div>\n </div>","PeriodicalId":601,"journal":{"name":"Iranian Polymer Journal","volume":"32 12","pages":"1607 - 1626"},"PeriodicalIF":2.4000,"publicationDate":"2023-09-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Properties and biodegradation modeling of abiotically treated modified-cobalt stearate filled polypropylene films\",\"authors\":\"Sunil Sable, Sanjeev Ahuja\",\"doi\":\"10.1007/s13726-023-01228-y\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>The present work studies the effects of abiotic pretreatment on the properties and biodegradability of the modified cobalt stearate pro-degradant filled polypropylene films, and on the eco-toxicity of their biodegraded products. Before abiotic pretreatment, their processability was confirmed by rheological studies. After abiotic pretreatment, FTIR revealed their carbonyl index increased on increasing the pro-degradant loading. Their GPC results showed significant decrease in molecular weight, thus indicating chain scission and intermediate formation. Their thermal stability also reduced as demonstrated by TGA. Their DSC and XRD analyses showed decreased crystallinity thereby indicating increased biodegradability. Their biodegradation was measured following ASTM D 5338, which showed a significant increase with abiotic pretreatment and the same was substantiated by GPC. The biodegradation kinetics followed Komilis model which showed that the degradation rate reached a maximum of 0.407–0.730% per day at 15–25th day. Readily hydrolysable carbon and its hydrolysis rate constant substantially enhanced with modified pro-degradant content. High readily hydrolyzable carbon rate constant caused the occurrence of a prominent growth phase. SEM also confirmed that the surface morphology of each film became increasingly rougher subsequent to both abiotic and biotic treatments, and with increasing pro-degradant loading. The eco-toxicity tests confirmed the nontoxicity of biodegraded products. 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引用次数: 0
摘要
本工作研究了非生物预处理对改性硬脂酸钴预降解剂填充聚丙烯薄膜的性能和生物降解性的影响,以及对其生物降解产物的生态毒性的影响。在非生物预处理之前,流变学研究证实了它们的可加工性。经过非生物预处理后,FTIR显示它们的羰基指数随着助降解剂负载量的增加而增加。他们的GPC结果显示分子量显著降低,从而表明链断裂和中间体形成。TGA显示它们的热稳定性也降低了。它们的DSC和XRD分析显示结晶度降低,从而表明生物降解性增加。根据ASTM D 5338测定了它们的生物降解性,显示出随着非生物预处理的显著增加,GPC也证实了这一点。生物降解动力学遵循Komilis模型,该模型显示,在第15–25天,降解率达到每天0.407–0.730%的最大值。易水解碳及其水解速率常数随着改性的促降解剂含量而显著提高。高的易水解碳速率常数导致了显著生长阶段的出现。SEM还证实,在非生物和生物处理之后,随着促降解剂负载量的增加,每个膜的表面形态变得越来越粗糙。生态毒性试验证实了生物降解产品的无毒性。因此,这项工作表明,薄膜可以具有有用的包装应用。图形摘要
Properties and biodegradation modeling of abiotically treated modified-cobalt stearate filled polypropylene films
The present work studies the effects of abiotic pretreatment on the properties and biodegradability of the modified cobalt stearate pro-degradant filled polypropylene films, and on the eco-toxicity of their biodegraded products. Before abiotic pretreatment, their processability was confirmed by rheological studies. After abiotic pretreatment, FTIR revealed their carbonyl index increased on increasing the pro-degradant loading. Their GPC results showed significant decrease in molecular weight, thus indicating chain scission and intermediate formation. Their thermal stability also reduced as demonstrated by TGA. Their DSC and XRD analyses showed decreased crystallinity thereby indicating increased biodegradability. Their biodegradation was measured following ASTM D 5338, which showed a significant increase with abiotic pretreatment and the same was substantiated by GPC. The biodegradation kinetics followed Komilis model which showed that the degradation rate reached a maximum of 0.407–0.730% per day at 15–25th day. Readily hydrolysable carbon and its hydrolysis rate constant substantially enhanced with modified pro-degradant content. High readily hydrolyzable carbon rate constant caused the occurrence of a prominent growth phase. SEM also confirmed that the surface morphology of each film became increasingly rougher subsequent to both abiotic and biotic treatments, and with increasing pro-degradant loading. The eco-toxicity tests confirmed the nontoxicity of biodegraded products. The work thus illustrated that the films can have useful packaging applications.
期刊介绍:
Iranian Polymer Journal, a monthly peer-reviewed international journal, provides a continuous forum for the dissemination of the original research and latest advances made in science and technology of polymers, covering diverse areas of polymer synthesis, characterization, polymer physics, rubber, plastics and composites, processing and engineering, biopolymers, drug delivery systems and natural polymers to meet specific applications. Also contributions from nano-related fields are regarded especially important for its versatility in modern scientific development.