Viscoelastic characterization of a new guar gum derivative containing anionic carboxymethyl and cationic 2-hydroxy-3-(trimethylammonio)propyl substituents

Abstract

A new guar gum derivative (CMHTPG) containing anionic carboxymethyl and cationic 2-hydroxy-3-(trimethylammonio)propyl substituents was characterized with the help of a stress-controlled rheometer for its linear viscoelastic behavior in aqueous systems. The frequency-dependent elastic modulus ( G′) and viscous modulus ( G″) curves for 0.5, 1.0, 1.5 and 2.0 g/dl of aqueous CMHTPG solutions were found to cross at a given frequency. The crossover frequency value decreased with the increase of CMHTPG concentration. At 25 °C, the longest relaxation time was obtained to be 5.556 s for aqueous 2.0% CMHTPG solution while the shortest relaxation time to be 0.027 s for aqueous 0.5% CMHTPG solution, showing a strong concentration dependence on the viscoelastic properties. Moreover, the complex viscosity ( η*) of aqueous CMHTPG solution was found to increase with the increase of CMHTPG concentration, and to decrease with the increase of frequency. By investigating the viscoelastic properties of aqueous CMHTPG salt solutions containing various concentrations of NaCl, it was observed that the addition of NaCl could lead to a slight increase in the G′ , G″ or η* value. Temperature was confirmed to have an important influence on the viscoelastic properties of aqueous CMHTPG solution. For aqueous 1.0% CMHTPG solution, the activation energy reflecting the temperature sensitivity of the complex viscosity was determined at the frequency of 1.0 rad/s and found to be 16.94 kJ/mol.