Xiaoxue Xu , Bengang Zhang , Liping Yu , De Li , Zhigang Wu , Jiankun Liang , Hong Lei
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A dense cross-linked network structure improved the thermal stability of the resin. (3) The bonding strength and toughness of the resin were significantly improved when the content of GO was 0.1 wt%. However, due to the large specific surface area and the intense π-π interaction between sheets, GO was easy to agglomerate, and the properties of the resin with GO content of 0.4 wt% degraded sharply. (4) The crystallinity of the MF resin modified by GO decreased, and the surface energy and plastic deformation energy increased due to the increased fracture crack path and fracture surface of the resin, which was the macro-reason for the improvement of toughness. (5) The strong π-π interaction between GO sheets and π-π accumulation between triazine rings were like parallel “springs” in the molecular structure of the resin, which might be the internal reason for the improvement of toughness. 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引用次数: 0
摘要
本研究对三聚氰胺-甲醛(MF)树脂胶粘剂进行了氧化石墨烯(GO)改性,分析了改性树脂的化学结构、润湿性、粘接性能、拉伸性能、固化性能和热性能,并探讨了其增韧机理。结果表明(1)高摩尔比的 MF 树脂具有稳定的亚甲基醚键,容易在空间产生平行折叠,形成 π-π 堆积的超分子自组装特殊结构,具有增强分子结构韧性的潜力。(2)GO 中含有大量含氧活性官能团,可进一步降低中频树脂的固化温度。致密的交联网络结构提高了树脂的热稳定性。(3) 当 GO 的含量为 0.1 wt% 时,树脂的粘结强度和韧性显著提高。但是,由于 GO 的比表面积大,片材间的π-π相互作用强烈,GO 容易团聚,GO 含量为 0.4 wt%时树脂的性能急剧下降。(4)GO 改性后的中频树脂结晶度降低,由于树脂断裂裂纹路径和断裂面增大,表面能和塑性变形能增加,这是韧性提高的宏观原因。(5) GO 片之间的强π-π相互作用和三嗪环之间的π-π堆积在树脂分子结构中就像平行的 "弹簧",这可能是韧性提高的内在原因。此外,研究还证明这种特殊结构可以限制树脂中羟甲基的活性和游离甲醛的释放。
Melamine formaldehyde resin adhesive toughened with graphene oxide: Structures and properties
The melamine-formaldehyde (MF) resin adhesive was modified by graphene oxide (GO), the chemical structure, wettability, bonding performance, tensile properties, curing performance and thermal properties of the modified resin were analyzed, and the toughening mechanism was also discussed in this study. The results showed that: (1) The MF resin with a high molar ratio possessed stable methylene ether bonds, which could easily generate parallel folding in space to form a π-π stacking supramolecular self-assembly special structure, with the potential of enhancing the toughness of molecular structures. (2) GO contained a large number of oxygen-containing reactive functional groups, which could further lower the curing temperature of the MF resin. A dense cross-linked network structure improved the thermal stability of the resin. (3) The bonding strength and toughness of the resin were significantly improved when the content of GO was 0.1 wt%. However, due to the large specific surface area and the intense π-π interaction between sheets, GO was easy to agglomerate, and the properties of the resin with GO content of 0.4 wt% degraded sharply. (4) The crystallinity of the MF resin modified by GO decreased, and the surface energy and plastic deformation energy increased due to the increased fracture crack path and fracture surface of the resin, which was the macro-reason for the improvement of toughness. (5) The strong π-π interaction between GO sheets and π-π accumulation between triazine rings were like parallel “springs” in the molecular structure of the resin, which might be the internal reason for the improvement of toughness. In addition, it was also proved that this special structure could limit the activity of hydroxymethyl and the release of free formaldehyde in the resin.
期刊介绍:
Polymer Testing focuses on the testing, analysis and characterization of polymer materials, including both synthetic and natural or biobased polymers. Novel testing methods and the testing of novel polymeric materials in bulk, solution and dispersion is covered. In addition, we welcome the submission of the testing of polymeric materials for a wide range of applications and industrial products as well as nanoscale characterization.
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Novel testing methods and Chemical analysis
• mechanical, thermal, electrical, chemical, imaging, spectroscopy, scattering and rheology
Physical properties and behaviour of novel polymer systems
• nanoscale properties, morphology, transport properties
Degradation and recycling of polymeric materials when combined with novel testing or characterization methods
• degradation, biodegradation, ageing and fire retardancy
Modelling and Simulation work will be only considered when it is linked to new or previously published experimental results.