Phosphate removal from aqueous solutions by heat treatment of eggshell and palm fiber

Phosphate removal from wastewater and the correspondent sustainable technologies are urgent issues to solve since phosphorous causes eutrophication of water sources. The effect of heat treatment on the mixture eggshell (ES), rich in calcium carbonate, with fiber palm (F), rich in carbonaceous material for phosphate removal is here reported focusing on the effects of temperature and F/ES ratio. The gases obtained from the F pyrolysis process help to improve the Ca(OH)(2) formation. In samples with a ES/F ratio of 1/10 (ESF-1:10) the CaCO3 is mainly transformed into Ca(OH)(2) (83 %) at 600 degrees C instead of 800 degrees C. The obtained solids were employed for phosphate removal from aqueous solutions and characterized before and after P removal. The ESF-1:10 sample pyrolyzed at 600 degrees C exhibited the best adsorption performance (48.3 %) at 2 h while ES showed 6.5 % at the same experimental conditions. The pseudo-second-order model kinetic and Langmuir model isotherm provided better-fitting models for the adsorption behavior of P. The adsorption capacity using Langmuir model was 72.0 mg g(-1), and the pseudo-second-order kinetic model assumes that the removal process of adsorbate is controlled by chemical adsorption. These results show that the Ca(OH)(2) is responsible for the phosphate removal by ligand exchange followed by precipitation mechanism leading to the formation of apatite.

Automated summary

Phosphate removal from wastewater is a pressing issue due to its contribution to water eutrophication. This study explores the use of heat treatment on eggshell and palm fiber mixtures for phosphate removal, with the resulting samples showing improved adsorption performance. The removal process of phosphate is primarily controlled by chemical adsorption, with the formation of apatite through ligand exchange and precipitation mechanisms.