Investigations of mechanism of Ca2+ adsorption on silica and alumina based on Ca-ISE monitoring, potentiometric titration, electrokinetic measurements and surface complexation modeling

Research on Ca2+ adsorption onto the mineral surface is of significant importance with regard to geochemical processes. Sverjensky (Geochim Cosmochim Acta 70(10), 2427-2453, 2006) assumed that alkaline earths form two types of surface species on oxides: tetranuclear (> SOH)(2)(> SO-)(2)_M(OH)(+) and mononuclear > SO-_M(OH)(+). To look into the above assumption we investigated calcium adsorption on SiO2 and Al2O3 because they are the most widespread minerals in the environment. We have determined the proton surface charge, electrokinetic potential and metal adsorption as a function of pH. The Ca2+ uptake and concentration in the system were monitored by the calcium ion-selective electrode (Ca-ISE). The Ca-ISE measurements indicated a similar affinity of Ca2+ for both materials despite their differently charged surface, negative for silica and mainly positive for alumina. This may suggest that simple electrostatic interactions are not the primary driving force for calcium adsorption, and that solvation of calcium ions at the surface may be crucial. We have analyzed our experimental data using the 2-pK triple-layer model (2-pK TLM). Three calcium complexes on the mineral surface were reported. Two of them were the same for both oxides, i.e. the tetranuclear (SOH)(2)(> SO-)(2)_Ca2+ and mononuclear complexes > SO-_CaOH+. Additionally, minor contribution from >SOH horizontal ellipsis Ca2+ for silica was assumed. In the case of Al2O3 the hydrolyzed tetranuclear complexes (> SOH)(2)(> SO-)(2)_CaOH+ at pH > 7.5 occurred based on the modeling results. Two types of surface complexes suggested by Sverjensky allowed for the correct description of proton and calcium uptake for alumina. However, the electrokinetic data excluded hydrolyzed tetranuclear surface species for this oxide.

Automated summary

The research investigates calcium adsorption onto SiO2 and Al2O3 surfaces, finding similar affinity of Ca2+ for both minerals despite their different surface charges, suggesting that electrostatic interactions may not be the primary driving force. The study also identifies three calcium complexes on the mineral surface and suggests that solvation of calcium ions at the surface may play a crucial role in the adsorption process.