Foundations of Colloid Science, Volume 2Clarendon Press, 1987 - Colloids |
From inside the book
Results 1-3 of 38
Page 834
... diameter 234 nm to travel 1 diameter in a suspension at T = 298 K , assuming it moves in a straight line . ( Take the density of polystyrene to be 950 kg / m3 . ) Now calculate the time the particle takes to travel 5.3 μm , assuming it ...
... diameter 234 nm to travel 1 diameter in a suspension at T = 298 K , assuming it moves in a straight line . ( Take the density of polystyrene to be 950 kg / m3 . ) Now calculate the time the particle takes to travel 5.3 μm , assuming it ...
Page 858
... diameter , the diameter would not be a relevant physical length in the problem . In this limit , we may use the so - called decoupling approximation . The basis of the decoupling approximation is to assume that the correlations in eqn ...
... diameter , the diameter would not be a relevant physical length in the problem . In this limit , we may use the so - called decoupling approximation . The basis of the decoupling approximation is to assume that the correlations in eqn ...
Page 859
... diameters . Returning to our conceptual two - step construction of the dispersion , variation of potential with diameter requires that we generate the equivalent pair correlation function for a dispersion of spheres which have not only ...
... diameters . Returning to our conceptual two - step construction of the dispersion , variation of potential with diameter requires that we generate the equivalent pair correlation function for a dispersion of spheres which have not only ...
Contents
Contents of Volume I ix | 675 |
ADSORPTION FROM SOLUTION | 709 |
CHARACTERIZATION OF COLLOIDAL DISPERSIONS 1 | 710 |
Copyright | |
10 other sections not shown
Other editions - View all
Foundations of Colloid Science. Vol. 1-2. Collab. Lee R. White, Leonard R ... No preview available - 1992 |
Common terms and phrases
adsorbed adsorption approximation assumed behaviour bulk C-potential calculated Chapter Chem co-surfactant coagulation coalescence Colloid interface Sci colloidal dispersions compare with eqn component constant corresponding counterions diffuse dilute double layer droplets effect electrical electrokinetic electrolyte electrolyte concentration electrostatic emulsion equilibrium Establish eqn estimate Exercise experimental Faraday ferrofluid field film flow fluid force free energy given hard sphere head group Hunter hydrophilic increases interaction K₁ latex liquid measured micelles microemulsion molecules neutron neutron scattering Newtonian fluid non-ionic surfactant Note obtained occur Ottewill Overbeek parameters particles phase Phys Poisson-Boltzmann equation polymer potential potential determining ions pressure procedure pseudoplastic radius region repulsion result scattering shear rate shear stress shown in Fig solution specific adsorption spherical stability structure surface charge surfactant suspension temperature thermodynamic thin thixotropic values velocity visco-elastic viscometer viscosity volume fraction Waals zero