交叉连接
聚合物
同质性(统计学)
材料科学
链接(几何体)
高分子科学
复合材料
高分子化学
化学
数学
组合数学
统计
作者
Victoria A. Kong,Thomas Staunton,Jennifer E. Laaser
出处
期刊:Macromolecules
[American Chemical Society]
日期:2024-05-08
卷期号:57 (10): 4670-4679
被引量:48
标识
DOI:10.1021/acs.macromol.3c02565
摘要
High Resolution Image Download MS PowerPoint Slide Cross-link heterogeneity and topological defects have been shown to affect the moduli of polymer networks in the low-strain regime. Probing their role in the high-strain regime, however, has been difficult because of premature network fracture. Here, we address this problem by using a double-network approach to investigate the high-strain behavior of both randomly and regularly cross-linked networks with the same backbone chemistry. Randomly cross-linked poly( n -butyl acrylate) networks with target molecular weights between cross-links of 5–30 kg/mol were synthesized via free-radical polymerization, while regularly cross-linked poly( n -butyl acrylate) networks with molecular weights between cross-links of 7–38 kg/mol were synthesized via cross-linking of tetrafunctional star polymers. Both types of networks were then swollen in a monomer/cross-linker mixture, polymerized to form double networks, and characterized via uniaxial tensile testing. The onset of strain stiffening was found to occur later in regular networks than in random networks with the same modulus but was well-predicted by the target molecular weight between cross-links of each sample. These results indicate that the low- and high-strain behavior of polymer networks result from different molecular-scale features of the material and suggest that controlling network architecture offers new opportunities to both further fundamental understanding of architecture–property relationships and design materials with independently controlled moduli and strain stiffening responses.
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