The Colloidal Domain: Where Physics, Chemistry, Biology, and Technology MeetThe Colloidal Domain, Second Edition is an indispensable professional resource for chemists and chemical engineers working in an array of industries, including petrochemicals, food, agricultural, ceramic, coatings, forestry, and paper products. It is also a superb educational tool for advanced undergraduate and graduate-level students of physical chemistry and chemical engineering. |
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Page 117
... charge density to increase . 0 = ( H. van Olphen , Introduction to Clay Colloid Chemistry , Wiley- Interscience , New York , 1963 , p . 34. ) B 3.7.3 The Gouy - Chapman Theory Provides Insight into Ion Distribution Near Charged Surfaces ...
... charge density to increase . 0 = ( H. van Olphen , Introduction to Clay Colloid Chemistry , Wiley- Interscience , New York , 1963 , p . 34. ) B 3.7.3 The Gouy - Chapman Theory Provides Insight into Ion Distribution Near Charged Surfaces ...
Page 379
... charge per every 136 Å2 corresponds to a charge density of 0.12 C / m2 . When montmorillonite clays come into contact with water , the water molecules penetrate between the unit layers . This in- terlayer swelling increases the clay's ...
... charge per every 136 Å2 corresponds to a charge density of 0.12 C / m2 . When montmorillonite clays come into contact with water , the water molecules penetrate between the unit layers . This in- terlayer swelling increases the clay's ...
Page 380
... charge density is .7 x 10-2 C / m2 , while in water a value of 2.3 × 10-3 C / m2 is measured . These charge densities correspond to one charge per 7000 Å2 for water and 900 Å2 for 1.2 × 10-3 M HCl . These values are considerably lower ...
... charge density is .7 x 10-2 C / m2 , while in water a value of 2.3 × 10-3 C / m2 is measured . These charge densities correspond to one charge per 7000 Å2 for water and 900 Å2 for 1.2 × 10-3 M HCl . These values are considerably lower ...
Contents
Solutes and Solvents SelfAssembly | 1 |
Literature | 35 |
Related to Surface Tension and | 44 |
Copyright | |
15 other sections not shown
Common terms and phrases
acid adsorbed adsorption aggregation number amphiphilic aqueous behavior bilayer bulk calculate CHAPTER charge density charged surfaces chemical potential coagulation coefficient colloidal colloidal particles colloidal systems component concentration counterions curvature curve decreases depends determine diffusion dipole dispersion distance distribution DLVO theory double layer drop droplets effect electrical electrolyte electrostatic emulsion entropy equation equilibrium force formation free energy Hamaker constant head group hydrocarbon hydrocarbon chain increases interface ionic ions lamellar latex lipid liquid crystal measured membrane micellar micelles microemulsion molecular molecules monolayer monomer nucleation obtain occurs osmotic parameter phase diagram Poisson-Boltzmann equation polar polymer pressure properties protein radius repulsive result scattering separation shown in Figure shows solid solubility solvent spheres spherical stability structure surface charge surface potential surface tension surfactant surfactant film temperature term thermodynamic tion transition vesicles volume fraction Waals zero zeta potential