门控
材料科学
多孔性
弹性体
液态气体
多孔介质
稳态(化学)
膜
化学工程
化学
复合材料
生物物理学
热力学
物理
工程类
生物化学
生物
物理化学
作者
Zhizhi Sheng,Honglong Wang,Yongliang Tang,Miao Wang,Lizhi Huang,Lingli Min,Haiqiang Meng,Songyue Chen,Lei Jiang,Xu Hou
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2018-02-02
卷期号:4 (2): eaao6724-eaao6724
被引量:126
标识
DOI:10.1126/sciadv.aao6724
摘要
The development of membrane technology is central to fields ranging from resource harvesting to medicine, but the existing designs are unable to handle the complex sorting of multiphase substances required for many systems. Especially, the dynamic multiphase transport and separation under a steady-state applied pressure have great benefits for membrane science, but have not been realized at present. Moreover, the incorporation of precisely dynamic control with avoidance of contamination of membranes remains elusive. We show a versatile strategy for creating elastomeric microporous membrane-based systems that can finely control and dynamically modulate the sorting of a wide range of gases and liquids under a steady-state applied pressure, nearly eliminate fouling, and can be easily applied over many size scales, pressures, and environments. Experiments and theoretical calculation demonstrate the stability of our system and the tunability of the critical pressure. Dynamic transport of gas and liquid can be achieved through our gating interfacial design and the controllable pores' deformation without changing the applied pressure. Therefore, we believe that this system will bring new opportunities for many applications, such as gas-involved chemical reactions, fuel cells, multiphase separation, multiphase flow, multiphase microreactors, colloidal particle synthesis, and sizing nano/microparticles.
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