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Page 55
... temperature range ( MTR ) can clarify the relation between solubility and micellization of surfactants better than the Krafft point is given . It is also made clear that the temperature range for the MTR is based on the concentration ...
... temperature range ( MTR ) can clarify the relation between solubility and micellization of surfactants better than the Krafft point is given . It is also made clear that the temperature range for the MTR is based on the concentration ...
Page 56
... temperature upon cooling . The term " Krafft point " first appeared in the paper by Lawrence in 1935 , in which he interpreted the Krafft point as a phase transi- tion [ 5 ] . He wrote : " The Krafft point is then due to loosening of ...
... temperature upon cooling . The term " Krafft point " first appeared in the paper by Lawrence in 1935 , in which he interpreted the Krafft point as a phase transi- tion [ 5 ] . He wrote : " The Krafft point is then due to loosening of ...
Page 58
... point . The shape is similar to that of melting two hydrated surfac- tant solids , and also to a thermodynamic analysis of the Krafft point of a binary surfactant mixture whose view is based on a freezing point depression of a binary ...
... point . The shape is similar to that of melting two hydrated surfac- tant solids , and also to a thermodynamic analysis of the Krafft point of a binary surfactant mixture whose view is based on a freezing point depression of a binary ...
Contents
General | 1 |
Surfactant Aggregation | 55 |
Phase equilibria and thermodynamics of liquid and solid crystal | 86 |
Copyright | |
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accepted June acid adsorbed adsorption aggregates amine anionic aqueous solutions behavior bentonite benzocaine birefringence calculated capillary waves cationic cell chain Chem coagulation Colloid concentration constant contact angle copolymer creams crystal growth crystalline curve decrease density dependence determined dielectric diffusion coefficient dispersion dodecyl effect electrolyte electron emulsions enthalpy equation equilibrium ESASS ethoxylated ethylene oxide experimental fibers formation Fowkes function graft copolymer hydrated hydrophilic hydrophobic increase Interf Sci interface interfacial tension ions isotropic kinetics Krafft point Kratky lamellae latex latices layer liquid measurements membrane method micelles micro-emulsion microparacrystals mixture mol/l molecules NaCl Neumann obtained parameters particle Phys Chem polarization Polym Sci polymer potential precipitation pressure ratio salt sample scattering sediment shear shear rate shown in Fig shows solid phase solubility solvent spectra structure surface tension surfactant Table temperature tion values viscosity x-ray Zeta zetapotential