Ever since the first volume appeared in 1969, this series has received good reviews in a variety of periodicals published in different corners of the world. It would seem that the work has fulfilled its purpose as outlined in the Preface to Volume 1. The rapidly increasing interest in surface and colloid science by people engaged in industrial research and development, and in environmental, ecological, medical, pharmaceutical, and other areas, justifies the continuation of such an effort. The Surface and Colloid Science series originated with John Wiley and Sons and has been continued with…mehr
Ever since the first volume appeared in 1969, this series has received good reviews in a variety of periodicals published in different corners of the world. It would seem that the work has fulfilled its purpose as outlined in the Preface to Volume 1. The rapidly increasing interest in surface and colloid science by people engaged in industrial research and development, and in environmental, ecological, medical, pharmaceutical, and other areas, justifies the continuation of such an effort. The Surface and Colloid Science series originated with John Wiley and Sons and has been continued with Plenum Press. This volume is the third with the present publisher, and is the best assurance of our mutual interest to proceed with this work. Some books in the series, as was the case with Volume 11, may appear under the editorship of other workers in the field. For reasons of continuity, a sequential numbering system will be maintained. This editor hopes to provide the scientific and technical community with high-quality contributions in surface and colloid science in the future. He invites specialists to submit definitive chapters on any topic within the broad area of our discipline for inclusion in this series.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
1. Polymers at Interfaces and in Disperse Systems.- 1. Introduction.- 2. Polymers at Interfaces.- 2.1. General Features.- 2.2. Theoretical Approaches.- 2.3. Experimental Approaches.- 2.4. Experimental Results.- 3. Particle Interactions in the Presence of Polymers.- 3.1. General Features.- 3.2. Theoretical Approaches.- 3.3. Experimental Approaches.- 4. Dispersion Stability in the Presence of Polymers.- 4.1. General Features.- 4.2. Theoretical Approaches.- 4.3. Experimental Approaches.- References.- 2. Characterization of Aqueous Colloids by Their Electrical Double-Layer and Intrinsic Surface Chemical Properties.- 1. Introduction.- 1.1. Overview.- 1.2. Origins.- 1.3. Ionization and Complexation Models.- 2. Experimental Characterization of Ionizable Surfaces and Colloids: Model-Independent Properties.- 2.1. Overview.- 2.2. Composition and Morphology.- 2.3. Surface Area.- 2.4. Types and Densities of Ionizable Surface Sites.- 2.5. Electrochemical Properties of Hydrosols.- 3. Electrical Double-Layer Models for Ionizable Surfaces and Colloids.- 3.1. Simple Diffuse Layer Models.- 3.2. Electrolyte Binding or Complexation Double-Layer Models.- References.- 3. Selective Flotation and Its Surface Chemical Characteristics.- 1. Main Features of the Flotation Process.- 1.1. Introduction.- 1.2. Industrial Applications of Flotation.- 1.3. Components of Flotation Systems.- 1.4. Technological Flexibility of Flotation.- 1.5. Criterion of Floatability.- 2. Surface Chemistry in Selective Flotation Systems.- 2.1. Contrasts and Similarities between Mono-Polar Collector-Acting Surfactants.- 2.2. Thio-Collector Adsorption on Metallic Sulfides.- 2.3. Flotation with Nonthio Collectors.- 2.4. Multipolar Surfactants used as Collectors, Chelating Agents, or Depressants Types and Structures.- 2.5. Surfactants Acting as Flotation Frothers.- 2.6. Mechanisms of Particle-Bubble Attachment.- 2.7. Kinetics of Flotation.- 3. Technology of Selective Flotation.- 3.1. Flowsheet Development.- 3.2. Instrumentation of Circuits and Modeling of Flotation Systems.- 4. Summary.- References.- 4. Interfacial Chemistry of Mineral Processing Separations.- 1. Introduction.- 2. Classification of Separation Methods in the Field of Mineral Processing.- 3. Physicochemical Methods of Separation.- 3.1. Classification of Various Methods.- 3.2. Effect of Particle Size.- 3.3. Flotation Methods.- 3.4. Colloidal Separation Methods.- 4. Physicochemical Beneficiation Processes.- References.- 5. The Suspension Effect.- 1. Introduction.- 2. Brief Historical Review of Principal Investigations of the Suspension Effect.- 3. On the Method of Determination of the Suspension Effect.- 4. The Principal Regularities of the Suspension Effect in Simple Disperse Systems with One Disperse Component.- 4.1. Universality of the Suspension Effect.- 4.2. The Relationship between the Sign of the Suspension Effect and That of the Particle Charge.- 4.3. Dependence of the Value of the Suspension Effect on the Concentration of the Particles.- 4.4. Dependence of the Value of the Suspension Effect on the Size of the Particles.- 4.5. Dependence of the Value of the Suspension Effect on the Charge Density and Potential of the Particles.- 4.6. Dependence of the Value of the Suspension Effect on the Concentration of Cross-Linking Agent in an Ion-Exchange Resin.- 4.7. Dependence of the Value of the Suspension Effect on the Concentration of Electrolyte in the Equilibrium Liquid and the Salt Bridge.- 4.8. Temperature Dependence of the Suspension Effect.- 5. On the Nature of the Suspension Effect.- 6. Experimental Confirmation of the Regularities in the Suspension Effect for Dispersions of Ion-Exchange Resins Following from Equation (46).- 7. Methods of Investigation of the Properties of Disperse Systems Based on the Suspension Effect.- 7.1. Determination of the Sign of the Particle Charge.- 7.2. Determination of the Isoelectric Point.- 7.3. Estimation of the Specific Surface.- 7.4. Estimation of the Location of Fixed Charge.-
1. Polymers at Interfaces and in Disperse Systems.- 1. Introduction.- 2. Polymers at Interfaces.- 2.1. General Features.- 2.2. Theoretical Approaches.- 2.3. Experimental Approaches.- 2.4. Experimental Results.- 3. Particle Interactions in the Presence of Polymers.- 3.1. General Features.- 3.2. Theoretical Approaches.- 3.3. Experimental Approaches.- 4. Dispersion Stability in the Presence of Polymers.- 4.1. General Features.- 4.2. Theoretical Approaches.- 4.3. Experimental Approaches.- References.- 2. Characterization of Aqueous Colloids by Their Electrical Double-Layer and Intrinsic Surface Chemical Properties.- 1. Introduction.- 1.1. Overview.- 1.2. Origins.- 1.3. Ionization and Complexation Models.- 2. Experimental Characterization of Ionizable Surfaces and Colloids: Model-Independent Properties.- 2.1. Overview.- 2.2. Composition and Morphology.- 2.3. Surface Area.- 2.4. Types and Densities of Ionizable Surface Sites.- 2.5. Electrochemical Properties of Hydrosols.- 3. Electrical Double-Layer Models for Ionizable Surfaces and Colloids.- 3.1. Simple Diffuse Layer Models.- 3.2. Electrolyte Binding or Complexation Double-Layer Models.- References.- 3. Selective Flotation and Its Surface Chemical Characteristics.- 1. Main Features of the Flotation Process.- 1.1. Introduction.- 1.2. Industrial Applications of Flotation.- 1.3. Components of Flotation Systems.- 1.4. Technological Flexibility of Flotation.- 1.5. Criterion of Floatability.- 2. Surface Chemistry in Selective Flotation Systems.- 2.1. Contrasts and Similarities between Mono-Polar Collector-Acting Surfactants.- 2.2. Thio-Collector Adsorption on Metallic Sulfides.- 2.3. Flotation with Nonthio Collectors.- 2.4. Multipolar Surfactants used as Collectors, Chelating Agents, or Depressants Types and Structures.- 2.5. Surfactants Acting as Flotation Frothers.- 2.6. Mechanisms of Particle-Bubble Attachment.- 2.7. Kinetics of Flotation.- 3. Technology of Selective Flotation.- 3.1. Flowsheet Development.- 3.2. Instrumentation of Circuits and Modeling of Flotation Systems.- 4. Summary.- References.- 4. Interfacial Chemistry of Mineral Processing Separations.- 1. Introduction.- 2. Classification of Separation Methods in the Field of Mineral Processing.- 3. Physicochemical Methods of Separation.- 3.1. Classification of Various Methods.- 3.2. Effect of Particle Size.- 3.3. Flotation Methods.- 3.4. Colloidal Separation Methods.- 4. Physicochemical Beneficiation Processes.- References.- 5. The Suspension Effect.- 1. Introduction.- 2. Brief Historical Review of Principal Investigations of the Suspension Effect.- 3. On the Method of Determination of the Suspension Effect.- 4. The Principal Regularities of the Suspension Effect in Simple Disperse Systems with One Disperse Component.- 4.1. Universality of the Suspension Effect.- 4.2. The Relationship between the Sign of the Suspension Effect and That of the Particle Charge.- 4.3. Dependence of the Value of the Suspension Effect on the Concentration of the Particles.- 4.4. Dependence of the Value of the Suspension Effect on the Size of the Particles.- 4.5. Dependence of the Value of the Suspension Effect on the Charge Density and Potential of the Particles.- 4.6. Dependence of the Value of the Suspension Effect on the Concentration of Cross-Linking Agent in an Ion-Exchange Resin.- 4.7. Dependence of the Value of the Suspension Effect on the Concentration of Electrolyte in the Equilibrium Liquid and the Salt Bridge.- 4.8. Temperature Dependence of the Suspension Effect.- 5. On the Nature of the Suspension Effect.- 6. Experimental Confirmation of the Regularities in the Suspension Effect for Dispersions of Ion-Exchange Resins Following from Equation (46).- 7. Methods of Investigation of the Properties of Disperse Systems Based on the Suspension Effect.- 7.1. Determination of the Sign of the Particle Charge.- 7.2. Determination of the Isoelectric Point.- 7.3. Estimation of the Specific Surface.- 7.4. Estimation of the Location of Fixed Charge.-
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