Interrelation between the thermodynamic and viscometric behaviour of aqueous solutions of hydrophobically modified ethyl hydroxyethyl cellulose

Aqueous solutions of a commercial sample of hydrophobically modified ethyl hydroxyethyl cellulose (HC, M-w = 100 kg/mol, nonylphenol substitution ca. 1.7 mol%) were studied with respect to their demixing behaviour and flow ch aracteristics. Phase separation temperatures were measured turbidimetricall y and by determining the first discernible macroscopic phase separation. In some cases demixing was also monitored viscometrically. Phase volume ratio s yielded a critical polymer concentration of 1.87 wt.% HC (displaced consi derably our of the minimum of the demixing curve towards higher polymer con centrations) and a lower critical solution temperature of 47 degrees C. Mod el calculations of the spinodal curve indicate a moderately exothermal heat of mixing. This conclusion is backed by the intrinsic viscosities determin ed from 25 to 55 degrees C. In this T-range [eta] falls in a sigmoidal mann er to approximately one forth of its value at the lowest temperature (430 m l/g). In spite of short, stiff chains and high dilution (max. 2.5 wt.% HC) these liquids have a highly developed tendency of shear thinning. Further, they exhibit an uncommonly large critical excess viscosity and the dependen cies of the zero shear viscosities on composition and temperature show seve ral peculiarities. All these findings and the observed shear induced expans ion of the homogenous region by more than 5 degrees C are explained consist ently in terms of long-lived clusters between the hydrophobic entities of H C established under equilibrium conditions. (C) 1999 Elsevier Science Ltd. All rights reserved.