材料科学
石墨烯
热重分析
胶粘剂
热稳定性
化学工程
氧化物
乳液聚合
堆积
复合材料
聚合物
聚合
乳状液
粒子(生态学)
X射线光电子能谱
肺表面活性物质
氢键
胶体
热的
基质(水族馆)
复合数
纳米尺度
粒径
混合材料
聚乙烯
作者
Pei Qin,Sepideh Ranji,Sang‐Ho Lee,Myung Cheon Lee
标识
DOI:10.1021/acsami.5c21063
摘要
-acrylic acid) copolymer, P(n-BA-stat-AA), as an auxiliary polymeric surfactant, thereby avoiding the colloidal instability commonly observed with conventional low-molecular-weight surfactants. FT-IR, Raman, and XPS analyses confirmed a sequential "adsorption-grafting-encapsulation" mechanism. P(n-BA-stat-AA) first adsorbs onto GO via hydrogen bonding and electrostatic attraction, then may partially grafts through radical reactions, and is finally encapsulated by the growing polymer shell. This process partially restored the π-π stacking and incorporated GO as cross-linking nodes. The resulting latex has a narrow modal particle diameter of about 200 nm and remains stable for several months. Incorporating 4 wt % GO increased the 180° peel strength to 19.11 N/25 mm, extended the shear holding time from 3 to 1388 min, and raised the shear-adhesion-failure temperature from 50.8 to 115.6 °C, demonstrating simultaneous improvements in adhesion, cohesion, and heat resistance. Thermogravimetric analysis revealed delayed backbone degradation and reduced mass-loss rates, confirming the thermal-shielding and diffusion-barrier effects of the layered filler. Overall, these findings establish a clear structure-property relationship: electrostatic repulsion from GO and steric hindrance from P(n-BA-stat-AA) together generate a nanoconfined hybrid network, imparting exceptional mechanical durability and thermal stability. This approach offers a promising pathway to high-performance water-based PSAs.
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