The Colloidal Domain: Where Physics, Chemistry, Biology, and Technology MeetFrom reviews of the first edition: "Very well written and brings a focus and a perspective that are not currently available in one convenient volume, especially one that is suitable for self-study or as a teaching tool." -Colloid and Interface Science "A revolutionary approach [to] writing an up-to-date text on 'The Colloidal Domain' and its origin in and impact on physics, chemistry, biology, and technology." -Advanced Materials "The authors should be congratulated for producing such a well-written text that is full of illustrations and formulas." -Chemistry and Industry This new edition of Evans and Wennerström's critically acclaimed text provides students and professionals with a comprehensive and up-to-date treatment of colloid science theory, methods, and applications. Emphasizing the molecular interactions that determine the properties of colloidal systems, the authors provide an authoritative account of critical developments in colloid science that have occurred over the past several decades. Combining all of the best features of a professional reference and a student text, The Colloidal Domain, Second Edition features: * Concept maps preceding each chapter that put subject matter into perspective * Numerous worked examples-many new to this edition-illustrating key concepts * More than 250 high-quality illustrations that help clarify processes described * A new chapter that integrates the development of colloid science and technology in the twentieth century with challenges facing the field today The Colloidal Domain, Second Edition is an indispensable professional resource for chemists and chemical engineers working in a range of areas, including the petrochemical, food, agricultural, ceramic, coatings, forestry, and paper industries. It is also a superb educational tool for advanced undergraduate and graduate-level students of physical chemistry and chemical engineering. |
From inside the book
Results 1-3 of 84
Page 158
... formation . The isodesmic model describes the association of some dyes in aqueous solution quite well , but it is less successful as a description of the formation of micelles because the model does not predict a CMC . Its basic ...
... formation . The isodesmic model describes the association of some dyes in aqueous solution quite well , but it is less successful as a description of the formation of micelles because the model does not predict a CMC . Its basic ...
Page 541
... formation , the processes of drop formation and coalescence compete , and the fastest - for- med proper surfactant film leads to the longest - lived drop . While new O / W interface is being created , surfactant interfacial density is ...
... formation , the processes of drop formation and coalescence compete , and the fastest - for- med proper surfactant film leads to the longest - lived drop . While new O / W interface is being created , surfactant interfacial density is ...
Page 625
... formation of , 304-306 transport properties of , 306 Microemulsions , 550-568 Microscopy atomic force ( AFM ) , 86-90 , 287 electrophoresis and , 436-437 fluorescence , 83-85 lateral force ( LFM ) , 89–90 polarized light , 296 , 313 ...
... formation of , 304-306 transport properties of , 306 Microemulsions , 550-568 Microscopy atomic force ( AFM ) , 86-90 , 287 electrophoresis and , 436-437 fluorescence , 83-85 lateral force ( LFM ) , 89–90 polarized light , 296 , 313 ...
Contents
Solutes and Solvents SelfAssembly | 1 |
Surface Chemistry and Monolayers | 45 |
3Electrostatic Interactions in Colloidal | 99 |
Copyright | |
14 other sections not shown
Common terms and phrases
acid adsorbed adsorption aggregation number amphiphilic aqueous attractive behavior bilayer bulk calculate CHAPTER charge density charged surface chemical potential coagulation coefficient coil colloidal colloidal particles colloidal systems component concentration counterions curvature curve decreases depends determine diffusion dipole dispersion distance distribution DLVO theory double layer droplets effect electrolyte electrostatic electrostatic interactions emulsion entropy equation equilibrium example force free energy head group hydrocarbon hydrophobic illustrated increases interac interface ionic kJ/mol lamellar latex lipid measured membrane micellar micelles microemulsion molecular molecules monolayer monomer nucleation obtain occurs osmotic osmotic pressure parameter phase diagram Poisson-Boltzmann equation polar polymer pressure properties protein R₁ radius range regular solution repulsive result Section shown in Figure shows solid solubility solvent spherical stability structure surface charge surface potential surface tension surfactant surfactant film temperature term thermodynamic tion transition vesicles Waals zeta potential