Selective and enhanced nickel adsorption from sulfate- and calcium-rich solutions using chitosan

Nickel (Ni) is an economically important metal characterized by its mechanical strength and anticorrosion properties. With the increasing industrial demand for Ni and the depleting accessible Ni primary ores, sustainable technologies are required for the recovery of this metal from alternative resources. In this study, adsorption using chitosan was investigated as a sustainable technique to recover Ni from sulfate (SO42-) and calcium (Ca) rich secondary resources. The effects of pH, contact time, and the presence of SO42- and Ca on Ni adsorption were investigated in batch experiments. Chemical speciation modeling was performed to analyze how the predominant Ni species present under different conditions may affect the efficiency of the adsorption process. The comparison of chitosan's maximum Ni adsorption capacities in the absence (1.00 mmol/g) and presence (1.49 mmol/g) of 500 mM SO42- and 10 mM Ca indicated the positive effect of these ions on Ni adsorption. The predominance of the neutrally charged NiSO40 species in Ni/SO42- system has contributed to the enhanced Ni adsorption on chitosan as verified by X-ray photoelectron spectroscopy (XPS) analysis. However, kinetic studies confirmed that the Ni adsorption rate decreased by 4.5 times when SO42- was present. The subsequent continuous Ni adsorption from a real SO42--rich leachate in a column setup revealed that chitosan is selective for Ni over Ca and Cr with selectivity quotients of 9.6 (K-Ni/Ca) and 3.0 (K-Ni/Cr). Overall, this study indicated that Ni complexation with SO42- enhances the Ni adsorption capacity of chitosan, but slows down the adsorption process.

Automated summary

This study investigated the use of chitosan as a sustainable technique for nickel recovery, with a focus on the complexation of sulfate with nickel to enhance chitosan's adsorption capacity. The research found that while sulfate complexation improved nickel adsorption, it also slowed down the adsorption process.