Determination of zeta potential and cationic demand in ECF and TCF bleached pulp from eucalyptus and flax. Influence of measuring conditions

The electrical nature of cellulose fibres is known to govern flocculation, retention and drainage mechanisms during the papermaking process. Zeta (zeta) potential provides useful information towards better control of wet-end chemistry in respects such as the dosaging of chemical aids. The purpose of this work was to study two electrokinetic properties (zeta potential and cationic demand) in ECF (elementary chlorine free) and TCF (totally chlorine free) bleached pulps from eucalyptus and flax, and examine the influence of pH and conductivity on measurements of such properties made with various methods based on the streaming potential, electrophoresis, polyelectrolyte titration and colloidal titration. Measurements of the electrokinetic properties made at high conductivities (C > 0.1 mS/cm) afforded no discrimination between pulp types in terms of electric charge. In fact, the conductivity used had a strong influence on measurements and shifted zeta potential to less negative values at high levels and to more negative values at low levels. The streaming potential technique proved to be more sensitive to changes in the properties (pH and conductivity) of the fibre suspension than did electrophoresis. Conductivity also influenced polyelectrolyte adsorption in the determination of cationic demand. The study also involved assessing the effect of low conductivities (0.01 < C < 0.1 mS/cm), which allowed fibre types and bleaching processes to be easily distinguished. Based on the results, accurately characterizing and identifying not only pulp types, but also the effects of mechanical, chemical and biochemical treatments on fibres, requires measuring the electrokinetic properties at a fixed pH and low conductivity.