毛细管悬浮液:通过毛细管力形成的颗粒网络。
Capillary suspensions: Particle networks formed through the capillary force.
作者信息
Koos Erin
机构信息
Institute for Mechanical Process Engineering and Mechanics, Karlsruhe Institute of Technology (KIT), Straße am Forum 8, 76131 Karlsruhe, Germany.
出版信息
Curr Opin Colloid Interface Sci. 2014 Dec 1;19(6):575-584. doi: 10.1016/j.cocis.2014.10.004.
Abstract
The addition of small amounts of a secondary fluid to a suspension can, through the attractive capillary force, lead to particle bridging and network formation. The capillary bridging phenomenon can be used to stabilize particle suspensions and precisely tune their rheological properties. This effect can even occur when the secondary fluid wets the particles less well than the bulk fluid. These materials, so-called capillary suspensions, have been the subject of recent research studying the mechanism for network formation, the properties of these suspensions, and how the material properties can be modified. Recent work in colloidal clusters is summarized and the relationship to capillary suspensions is discussed. Capillary suspensions can also be used as a pathway for new material design and some of these applications are highlighted. Results obtained to date are summarized and central questions that remain to be answered are proposed in this review.
摘要
向悬浮液中添加少量第二流体,通过吸引性毛细力可导致颗粒桥连和网络形成。毛细桥连现象可用于稳定颗粒悬浮液并精确调节其流变特性。即使第二流体对颗粒的润湿性不如主体流体,这种效应仍可能发生。这些材料,即所谓的毛细悬浮液,一直是近期研究的主题,研究内容包括网络形成机制、这些悬浮液的性质以及如何改变材料性能。总结了近期在胶体团簇方面的工作,并讨论了其与毛细悬浮液的关系。毛细悬浮液还可作为新材料设计的途径,文中突出介绍了其中一些应用。本综述总结了迄今为止获得的结果,并提出了有待解答的核心问题。
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