具有分离结构的功能化氧化石墨烯-溴丁基橡胶复合材料增强气体阻隔性能

IF 2.1 4区材料科学 Q3 MATERIALS SCIENCE, COMPOSITES

Plastics, Rubber and Composites Pub Date : 2021-11-25 DOI:10.1080/14658011.2021.2008702

Yingjun Li, Qin He, Hao Zhang, Aojie Liu, Zhiyu He, Yin‐tao Li, Yuanlin Zhou

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引用次数: 1

摘要

采用静电自组装法制备了具有分离结构的石墨烯基弹性体复合材料。采用扫描电镜(SEM)和透射电镜(TEM)对复合材料的形貌和微观结构进行了表征。分离的网状结构使得BIIR复合材料具有较低的透气性。GTA-GO掺入量为0.4 wt-%时，与纯BIIR相比，氦渗透系数降低约63%。拉伸强度和伸长率随GTA-GO含量的增加而增加。这是由于GTA-GO在BIIR基体中具有完全剥落、均匀分散和偏析结构。实验结果表明，这种胶乳与片状填料之间的静电自组装方法是设计和生产具有良好气体阻隔性能的高分子纳米复合材料的有效策略。研究结果将有效促进阻隔聚合物在防护服、储气装置和涂料等领域的应用。

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Functionalised graphene oxide-bromobutyl rubber composites with segregated structure for enhanced gas barrier properties

ABSTRACT Graphene-based elastomer composites with a segregated structure were prepared by electrostatic self-assembly. The morphology and microstructures of the composites were characterised by scanning electron microscope (SEM) and transmission electrical microscope (TEM). The segregated network leads to a low gas permeability coefficient for BIIR composites. With the incorporation as low as 0.4 wt-% GTA-GO, the helium permeability coefficient decreased about 63% when compared with that of neat BIIR. The tensile strength and percentage elongation increased with an increase in the GTA-GO content. This is attributed to the complete exfoliation, uniform dispersion and the segregated structure of GTA-GO in the BIIR matrix. These results demonstrate that such electrostatic self-assembly method between latex and sheet-fillers is an effective strategy to design and produce polymeric nanocomposites with good gas barrier properties. The results will effectively promote the application of barrier polymer in the production of protective clothing, gas storage devices and coatings.

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来源期刊

Plastics, Rubber and Composites 工程技术-材料科学：复合

CiteScore

4.10

自引率

0.00%

发文量

审稿时长

4 months

期刊介绍： Plastics, Rubber and Composites: Macromolecular Engineering provides an international forum for the publication of original, peer-reviewed research on the macromolecular engineering of polymeric and related materials and polymer matrix composites. Modern polymer processing is increasingly focused on macromolecular engineering: the manipulation of structure at the molecular scale to control properties and fitness for purpose of the final component. Intimately linked to this are the objectives of predicting properties in the context of an optimised design and of establishing robust processing routes and process control systems allowing the desired properties to be achieved reliably.