Foundations of Colloid Science, Volume 2Clarendon Press, 1987 - Colloids |
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Page 863
... direction as well as the magnitude of Q. The most interesting case is when all particles are aligned parallel to a given direction in the sample , in which case p ( 0 , q ) is a 8 - function , and I ( Q ) will show the symmetry of the ...
... direction as well as the magnitude of Q. The most interesting case is when all particles are aligned parallel to a given direction in the sample , in which case p ( 0 , q ) is a 8 - function , and I ( Q ) will show the symmetry of the ...
Page 869
... direction of the neutron's magnetic moment relative to H ( i.e. the polarization of the beam ) . Since the neutron ... direction . In a real sample , this will not generally be true , since at finite field there will always be thermal ...
... direction of the neutron's magnetic moment relative to H ( i.e. the polarization of the beam ) . Since the neutron ... direction . In a real sample , this will not generally be true , since at finite field there will always be thermal ...
Page 939
... direction of flow , ū is equal to the overall flow velocity , whereas ū = 0 in the direction perpendicular to the flow . Usually , u ' depends on direction but for isotropic flows u ' is independent of direction and that is the ...
... direction of flow , ū is equal to the overall flow velocity , whereas ū = 0 in the direction perpendicular to the flow . Usually , u ' depends on direction but for isotropic flows u ' is independent of direction and that is the ...
Contents
Contents of Volume I ix | 675 |
ADSORPTION FROM SOLUTION | 709 |
CHARACTERIZATION OF COLLOIDAL DISPERSIONS 1 | 710 |
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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