Site energy distribution analysis and influence of Fe_3O_4 nanoparticles on sulfamethoxazole sorption in aqueous solution by magnetic pine sawdust biochar

摘要

AbstractMagnetisation of carbonaceous adsorbents using iron oxides has been found to be one of the potential solutions for easy recovery of adsorbent after use. We evaluated the effects of Fe3O4nanoparticle addition on the physico-chemical properties of biochar and its sorption properties. Five adsorbents with varying amount of Fe3O4per mass of adsorbent (0%, 25%, 50%, 75% and 100%) were used to adsorb sulfamethoxazole (SMX), an emerging micropollutant. Five isotherm models were used to evaluate the sorption behaviour of SMX onto the adsorbents where Redlich-Peterson model was found to best describe the data. Based on this model, the approximate site energy distribution for each adsorbent was determined. Surface area and sorption capacity had strong negative linear relationship with the amount of Fe3O4per mass of adsorbent while the pore volume and saturation magnetisation of the adsorbent increased with increasing percentage of Fe3O4. The results of the approximate site energy distribution analysis showed that the addition of Fe3O4on biochar reduced the area under the frequency distribution curve of sorption site energies leading to the lowering of the sorption sites available for SMX. This could be attributed to the blockage of the hydrophobic surface of biochar reducing the hydrophobic interaction between SMX and biochar.Graphical abstractDisplay OmittedHighlights•Physico-chemical changes in biochar after magnetisation were evaluated.•Surface area linearly decreased with increasing Fe3O4loading on biochar.•Effects of Fe3O4on biochar using site energy distribution analysis were assessed.•Magnetisation of biochar decreased low energy sites but not the high energy sites.•Fe3O4addition on biochar reduced the sorption capacity of the biochar.Addition of Fe3O4in pine sawdust biochar lowered the low sorption site energies which could be attributed to the blockage of the hydrophobic surface of biochar.