Removal of Cylindrospermopsin by Adsorption on Granular Activated Carbon, Selection of Carbons and Estimated Fixed-Bed Breakthrough

Climate change and the increase in the availability of nutrients in aquatic environments have increased the occurrence of cyanobacterial blooms which can produce cyanotoxins such as cylindrospermopsin (CYN). Activated carbon adsorption have been proved to be efficient for CYN removal. In the present study, a carbon with high CYN adsorption capacity was identified between two granular activated carbons. For this carbon was estimated the operating time of a full-scale granular activated carbon column under different empty bed contact times (EBCT). The fixed-bed breakthrough was estimated using the Homogeneous Surface Diffusion Model (HSDM). Wood carbon showed greater capacity to remove CYN. The experimental equilibrium data best fitted Langmuir isotherm model, in which wood carbon had a maximum adsorption capacity of 3.67 mu g/mg and Langmuir adsorption constant of 0.2791 L/mu g. The methodology produced satisfactory results where the HSDM simulated the fixed-bed breakthrough with a coefficient of determination of 0.89, to the film diffusion coefficient (K-f) of 9 x 10(-6) m/s and surface diffusion coefficient (D-s) of 3 x 10(-16) m(2)/s. It was observed that the increase in EBCT promotes a reduction in the carbon use rate. The best carbon use rate found was 0.43 kg/m(3) for a EBCT of 10 min and breakthrough time of 183.6 h.

Automated summary

Climate change and nutrient increase in aquatic environments have led to an increase in cyanobacterial blooms, which produce cyanotoxins. A carbon with high adsorption capacity for cyanotoxins was identified in this study and its operating time in a full-scale column was estimated. Wood carbon showed the best performance in removing cyanotoxins.