posted on 2018-06-12, 08:13authored bySankar Das, Arnab Samanta, Gautam Gangopadhyay, Subhra Jana
Here, we report the development of
inorganic–organic hybrid
nanocomposites through selective modification of the negative outer
surfaces of halloysite nanoclays with two different organosilanes
having primary or secondary amine sites to be explored them as novel
and cost-effective adsorbents for the extraction of toxic inorganic
contaminants from aqueous solution. They possess excellent selectivity
for the adsorption of mercury, which shows monolayer molecular adsorption
over the nanocomposites. The adsorption kinetics of Hg(II) is very
fast and follows pseudo-second-order model compared to pseudo-first-order
model. A combined experimental and theoretical study demonstrated
that Hg(II) uptake by these nanocomposites is highly favorable and
spontaneous up to 40 °C, and beyond this temperature, the uptake
capacity gradually reduced. Temperature-dependent adsorption study
exhibits endothermicity at low temperature (≤40 °C) and
exothermicity beyond 40 °C. pH-dependent adsorption study showed
their high uptake capacity until pH 7, which reduced at alkaline pH.
All of the nanocomposites hold excellent adsorption capacity even
at low concentration of adsorbate, along with multicycle sorption
capability. The outstanding adsorption capacity as well as the easy
synthetic route to achieve these nanocomposites may attract researchers
to develop low-cost adsorbents to capture toxic metals, which in turn
regulate the permissible limit of these toxic metals in drinking water.