材料科学
复合材料
多孔性
聚氨酯
消散
解耦(概率)
刚度
压实
弹性体
变形(气象学)
数字图像相关
压缩(物理)
基质(化学分析)
振动
多孔介质
压力(语言学)
聚合物
应变能
纳米尺度
纳米结构
小角X射线散射
应力-应变曲线
抗压强度
挤压
细菌纤维素
微观力学
磁导率
纳米复合材料
变形机理
工作(物理)
作者
Maomin Zhen,Xi Zhang,Yali Guo,Xiaodong Li,Xi Zhang,J Zhang,Yibing Xia,Hao Jiang,Meishuai Zou
摘要
ABSTRACT This study presents a stress‐induced pore rupture strategy for decoupling cellular architecture from matrix properties in microcellular polyurethane elastomers. Controlled mechanical compression was applied to a single formulation to tune open porosity (14%–67%) while preserving matrix chemistry and nanoscale morphology, as verified by FTIR, XRD, and SAXS analysis. In situ CT imaging revealed distinct deformation mechanisms: closed‐cell structures deformed through gradual pore compression dominated by gas‐spring effects, whereas open‐cell networks exhibited immediate strut reorientation and extensive compaction governed by solid matrix deformation. Quantitative analysis showed that cellular deformation accounted for 81.2%–86.8% of total strain in open‐cell foams, compared with 69.2%–74.1% in closed‐cell systems. Increasing open porosity reduced stiffness by 27% but enhanced energy dissipation by 63%. Digital image correlation further demonstrated localized strain in closed‐cell foams and uniform stress redistribution in open‐cell architectures. Vibration testing revealed complementary performance, with high‐porosity foams suppressing resonance through viscous damping and low‐porosity foams providing superior high‐frequency isolation. This work establishes microstructure‐guided design principles for programming dynamic mechanical properties in polymer foams, offering a pathway toward lightweight material for vibration control and impact protection.
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