深入了解Zeta电位测量在生物聚合物薄膜制备

M. Sabbah, M. Esposito, P. Pierro, C. Giosafatto, L. Mariniello, R. Porta
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引用次数: 18

摘要

微粒子和纳米粒子电荷是决定乳剂和悬浮液物理稳定性的主要因素之一,可以通过测量所谓的“ζ电位”来量化。当所有的粒子都有一个大的负或正的zeta电位值时,它们会相互排斥,因此,悬浮液变得稳定。而zeta电位越接近0 mV,絮凝倾向越强。然而,Zeta电位是粒子在其环境中的特征,而不是粒子本身的特征。实际上,它在溶液中的净电荷影响了粒子周围的离子分布,从而导致反离子浓度的增加。这种影响延伸的区域被称为“双电层”(EDL), EDL分为两个区域(图1)。在第一个称为“stern层”的区域,离子与粒子具有相反的电荷,并且与它们紧密结合,随着它们移动。相反,第二层是“扩散层”,其中离子的附着强度较低,在其内部,随着粒子移动的离子和不移动的离子之间有一条边界线。该区域称为“滑移面”,称为水动力剪切面,滑移面中存在的势称为zeta势[1]。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Insight into Zeta Potential Measurements in Biopolymer Film Preparation
Microand nano-particle charge is one of the main factors determining the physical stability of both emulsions and suspensions and can be quantified by measuring their so called “zeta potential”. When all the particles have a large either negative or positive zeta potential value, they will repel each other and, as a consequence, the suspension becomes stable. By contrast, whether the zeta potential is close to 0 mV, the tendency for flocculation increases. Zeta potential is, however, a feature of the particle in its environment and not of the particle itself. In fact, its net charge in solution affects the ion distribution surrounding the particle, thus resulting in an increase in the concentration of counter-ions. The region over which this influence extends is called “electrical double layer” (EDL) and EDL splits into two regions (Figure 1). In the first, called “stern layer”, the ions are of opposite charge with respect to the particles and, being strongly bound to them, move with them. The second layer, conversely, is a “diffuse layer” where the ions are less strongly attached and, inside it, there is a boundary line between the ions moving with the particles and the not moving ones. This region, called “slipping plane”, is known as the surface of hydrodynamic shear and the potential existing in the slipping plane is called zeta potential [1].
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