Extensive industrial activities discharge huge amounts of different pollutants into water bodies. Among these
pollutants, heavy metals stand as the most poisonous species due to their resistance to biodegradation and their
short- and long-term exposure effects. More specific, Cr(VI) is one of the top-five toxic elements that pose potent
toxicity to the entire environmental system. In this study, six modified chitosan hydrogel composites (Categorized
in two groups and comprised of chitosan or carboxymethyl chitosan crosslinked with acrylamide and incorporating
aluminum oxide as an inorganic core) were prepared under the influence of gamma irradiation at an optimized
dose (30 kGy) as a facile, environmentally friendly technique. These hydrogels were employed for the removal of
Cr(VI) from aqueous solution considering various variables that influencing removal performance, taking structural
variation into consideration. The removal process was followed by the AFM to compare between the chromium
free and chromium-loaded surfaces. According to the experimental findings, the following circumstances were
ideal for maximizing dye uptake by the optimized samples: pH 2, 120-min contact duration, 0.1 g of sorbent, and
a metal concentration of 50 ppm. The maximum metal uptake was achieved by the prepared green sorbents
was found competitive (ranging from 48.9 to 51.5 mg/g). Moreover, all the investigated sorbents showed strong
removal efficiency and adsorption capability after four cycles of sorption/desorption. However, it was found that
the adsorption capacities of the second group's elements was higher than that of the first group. Additionally, the
data demonstrated that the adsorption process conformed the pseudo-first order kinetic isotherm and best fit the
Freundlich model imposing multilayer adsorption of Cr(VI) onto the sorbent matrix via several mechanisms which
is consistent with variable functionalities in the hydrogel matrix. |
