Sago Starch-Mixed Low-Density Polyethylene Biodegradable Polymer: Synthesis and Characterization

E. Hoque, T. Ye, L. Yong, K. M. Dahlan
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引用次数: 33

Abstract

This research focuses on synthesis and characterization of sago starch-mixed LDPE biodegradable polymer. Firstly, the effect of variation of starch content on mechanical property (elongation at break and Young’s modulus) and biodegradability of the polymer was studied. The LDPE was combined with 10%, 30%, 50%, and 70% of sago for this study. Then how the cross-linking with trimethylolpropane triacrylate (TMPTA) and electron beam (EB) irradiation influence the mechanical and thermal properties of the polymer was investigated. In the 2nd study, to avoid overwhelming of data LDPE polymer was incorporated with only 50% of starch. The starch content had direct influence on mechanical property and biodegradability of the polymer. The elongation at break decreased with increase of starch content, while Young’s modulus and mass loss (i.e., degradation) were found to increase with increase of starch content. Increase of cross-linker (TMPTA) and EB doses also resulted in increased Young’s modulus of the polymer. However, both cross-linking and EB irradiation processes rendered lowering of polymer’s melting temperature. In conclusion, starch content and modification processes play significant roles in controlling mechanical, thermal, and degradation properties of the starch-mixed LDPE synthetic polymer, thus providing the opportunity to modulate the polymer properties for tailored applications.
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西米淀粉-混合低密度聚乙烯可生物降解聚合物的合成与表征
研究了西米淀粉-混合LDPE可生物降解聚合物的合成与表征。首先,研究了淀粉含量的变化对聚合物力学性能(断裂伸长率和杨氏模量)和生物降解性的影响。在本研究中,LDPE分别与10%、30%、50%和70%的西米复合。然后研究了三甲基丙烷三丙烯酸酯(TMPTA)交联和电子束辐照对聚合物力学性能和热性能的影响。在第二项研究中,为了避免数据的压倒性,LDPE聚合物只掺入50%的淀粉。淀粉的含量直接影响聚合物的力学性能和生物降解性。断裂伸长率随淀粉含量的增加而降低,杨氏模量和质量损失(即降解)随淀粉含量的增加而增加。交联剂(TMPTA)和EB剂量的增加也导致聚合物的杨氏模量增加。而交联和EB辐照均能降低聚合物的熔融温度。综上所述,淀粉含量和改性工艺对淀粉混合LDPE合成聚合物的力学、热学和降解性能起着重要的控制作用,从而为定制应用提供了调节聚合物性能的机会。
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