Stability of disperse systems

P. C. Hiemen2, Principles of Colloid and Suf ace Chemisty, 2nd ed., Marcel Dekker, Inc., New York, 1986 R. D. Void and M. J. Void, Colloid and Inteface Chemisty, Addison-Wesley, Reading, Mass., 1983 H. Sonntag and K. Strenge, Coagulation and Stability of Disperse Systems, Halsted, New York, 1972 D. J. Shaw, Introduction to Colloid and Suf ace Chemisty, 3rd ed., Butterworth, London, 1980. 

Stumm, W., C. P. Huang, and S. R. Jenkins (1970), "Specific Chemical Interaction Affecting the Stability of Dispersed Systems", Croat. Chem. Acta 42, 223-245. 

Specific chemical interactions affecting the stability of dispersed systems. Croatica Chem. Acta 42 223-245 Su, C. Puls, R.W (2001) Arsenate and arsenite removal by zerovalent iron Kinetics, Redox transformation, and implications for in situ groundwater remediation. Environ. Sd. 

Sonntag, H., and Strenge, K., Coagulation and Stability of Disperse Systems, Halsted, New York, 1964. 

At the beginning, the electric double layer at the solid-aqueous electrolyte solution interface was characterized by the measurements of the electrokinetic potential and stability of dispersed systems. Later, the investigations were supported by potentiometric titration of the suspension, adsorption and calorimetric measurements [2]. Now, much valuable information on the mechanism of the ion adsorption can be obtained by advanced spectroscopic methods (especially infrared ATR and diffuse spectroscopy) [3], Mosbauer spectroscopy [4] and X-ray spectroscopy [5]. Some data concerning the interface potential were obtained with MOSFET [6], and AFM [7]. An enthalpy of the reaction of the metal oxide-solution systems can be obtained by... 

The development of the thermodynamics of thin films is related to the problem of stability of disperse systems. An important contribution to its solving are the works of the Russian scientists Derjaguin and Landau [1] and the Dutch scientists Verwey and Overbeek [2], known today as the DVLO theory. According to their concept the particular state of the thin liquid films is due to the change in the potential energy of molecular interaction in the film and the deformation of the diffuse electric layers. The thermodynamic characteristic of a state of the liquid in the thin film, as shown in Section 3.1, appears to be the dependence of disjoining pressure on film thickness, the n(/t) isotherm. The thermodynamic properties of... 

Stumm, W., Huang, C. P., and Jenkins, S. R., 1970, Specific chemical interactions affecting the stability of dispersed system Croat Chem. Acta, v. 42, p. 223-244. 

The stability of disperse systems is controlled by interparticulary attraction and repulsion forces, and by the range of the free energy of the particle surface. Pure water/oil-systems are not stable. 

The stability of dispersed systems is influenced by an enormous number of parameters. Part of them can be predicted by considering the theory of stability, others can be obtained by experiments, but the influence of some parameters could not be explained until now. 

Colloid Stability of Disperse Systems Containing Electrical Double Layers... 

It was shown by Izmailova et al that the rheological properties of adsorption layers formed with high molecular weight surfactants and biopolymers play an important role in ensuring the stability of disperse systems stabilized by such layers (see Chapters VI-VIII). 

The participation of colloidal particles in thermal motion (the entropic factor) was taken into consideration, mostly indirectly, in earlier studies dealing with the molecular-kinetic properties of disperse systems. Volmer was the first to realize the importance of the role that the thermal motion of colloidal particles played in controlling the formation and stabilization of disperse systems. However, the attempt to compare the work of surface formation and the entropic factor directly, undertaken by March, was not successful, since it was applied only to systems with high interfacial energy. 

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