材料科学
刚度(电磁)
饱和(图论)
吸附
复合材料
缩放比例
分子动力学
标度律
流离失所(心理学)
延伸率
机械
极限抗拉强度
结构工程
聚合物
纳米复合材料
纳米技术
刚度
扩展(谓词逻辑)
变形(气象学)
中尺度气象学
作者
Guan Junlei,Dai Li-jun,Cui‐Liu Fu,Wan-Chen Zhao,Xianbo Huang,Sun Zhao-yan
摘要
We employ coarse-grained molecular dynamics simulations to investigate interfacial reorganization in polymer-nanoparticle composites, focusing on the competing effects of chain rigidity (Kbend) and attractive strength (ɛ). Geometric constraints create a critical adsorption threshold ɛk. Below this threshold, increasing attraction converts loops and tails into extended trains, improving surface-parallel alignment. Beyond ɛk, saturation causes competitive displacement that fragments trains and reduces orientational order. Machine learning analysis identifies the average tail segment length, ⟨Ltail⟩, as the primary controlling parameter of interfacial thickness δRMS (relative importance >89%). The derived scaling laws describe how rigidity enhances tail extension efficiency. Attractive strength influences thickness indirectly through its effect on ⟨Ltail⟩ within adsorption saturation constraints. These results establish two design principles: using rigidity-controlled tail manipulation for precise thickness tuning and applying ɛk-optimized attraction to maximize adsorption efficiency. This provides concrete guidelines for engineering nanocomposite interfaces.
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