材料科学
渗透(认知心理学)
聚合物
化学物理
相(物质)
多孔介质
扩散
多孔性
马朗戈尼效应
旋节分解
化学工程
表面张力
复合材料
热力学
有机化学
工程类
神经科学
化学
物理
生物
作者
Fei Wang,Patrick Altschuh,Lorenz Ratke,Haodong Zhang,Michael Selzer,Britta Nestler
标识
DOI:10.1002/adma.201806733
摘要
Polymeric porous media (PPM) are widely used as advanced materials, such as sound dampening foams, lithium-ion batteries, stretchable sensors, and biofilters. The functionality, reliability, and durability of these materials have a strong dependence on the microstructural patterns of PPM. One underlying mechanism for the formation of porosity in PPM is phase separation, which engenders polymer-rich and polymer-poor (pore) phases. Herein, the phase separation in polymer solutions is discussed from two different aspects: diffusion and hydrodynamic effects. For phase separation governed by diffusion, two novel morphological transitions are reviewed: "cluster-to-percolation" and "percolation-to-droplets," which are attributed to an effect that the polymer-rich and the solvent-rich phases reach the equilibrium states asynchronously. In the case dictated by hydrodynamics, a deterministic nature for the microstructural evolution during phase separation is scrutinized. The deterministic nature is caused by an interfacial-tension-gradient (solutal Marangoni force), which can lead to directional movement of droplets as well as hydrodynamic instabilities during phase separation.
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