Alexander A. Baran, Yana A. Babich, Andrey A. Tarovsky, Natalia A. Mischuk
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引用次数: 22
Abstract
It has been shown that the electrophoretic mobility of large ion-exchanger particles (diameter, 250–1000 μm) or fibres (length, 100–1000 μm) in strong electric fields (100–1000 V cm−1) exceeds the electrophoretic mobility values typical for non-conducting particles by one or two orders of magnitude. This phenomenon was called “electrophoresis of the second kind” or “superfast electrophoresis”. The mobility of such particles depends on the conductivity ratio between the particles and medium and increases linearly with the electric field gradient and the particle size. This is in contrast to classical electrophoresis which does not depend on these parameters.
The effect of electrolytes and pH on the electrophoretic mobility in strong fields is due to the change in the conductivity ratio mentioned above. Changes in the electric double layer parameters do not affect the mobility.
Electrophoresis of the second kind is due to the interaction of a strong electric field with the space charge near the surface of unipolar conducting particles. It occurs only when the conductivity of particles exceeds the conductivity of the medium. New methods to observe this phenomenon were developed.
研究表明,在强电场(100-1000 V cm−1)中,大离子交换剂颗粒(直径250-1000 μm)或纤维(长度100-1000 μm)的电泳迁移率比非导电颗粒的典型电泳迁移率高出一到两个数量级。这种现象被称为“第二类电泳”或“超高速电泳”。这种粒子的迁移率取决于粒子与介质之间的电导率比,并随着电场梯度和粒子尺寸的增大而线性增加。这与不依赖于这些参数的经典电泳相反。电解质和pH值对强电场中电泳迁移率的影响是由于上述电导率比的变化。双电层参数的变化不影响迁移率。第二类电泳是由于强电场与单极导电粒子表面附近的空间电荷相互作用而产生的。只有当粒子的导电性超过介质的导电性时才会发生这种现象。人们发展了观察这一现象的新方法。
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