Abstract:
Facile in situ synthesis of Graphene oxide–gold (GO–Au), graphene oxide-silver (GOAg)
and reduced graphene oxide-ZnS (rGO-ZnS) nanocomposite has been reported.
These composites were studied for their applications as (i) an adsorbent materials for
the removal of some toxic industrial dyes from aqueous medium, (ii) as a catalyst for
the individual and simultaneous reduction of mixture of dyes and nitro compound and
as (iii) an antibacterial agent for the destruction of some harmful microorganisms
existent in wastewater. Graphene oxide, GO was prepared using a modified Hummers
method. Gold (Au), silver (Ag) and zinc sulphide (ZnS) nanoparticles were integrated
on GO sheets by reducing Au+ ions, Ag+ ions and Zn++ ions on the surfaces of GO
sheets using sodium citrate, sodium borohydride (NaBH4) and sodium sulphide in
DMF as a reducing agent respectively. Prepared nanocomposites were extensively
characterized for their morphology and composition using field emission scanning
electron microscopy (FESEM), transmission electron microscopy (TEM), elemental
dispersive X-ray analysis (EDX), X-ray diffraction (XRD), Fourier transform infra-red
(FT-IR) spectroscopy and thermal gravimetric analysis (TGA) techniques. All prepared
nanocomposites demonstrated remarkable adsorption capacities and desorption for
malachite green (MG) and ethyl violet (EV) dyes. Various experimental parameters
affecting adsorptive behavior of nanocomposites such as temperature, pH, time of
contact between dyes and adsorbent, and adsorbent dose were evaluated thoroughly.
Experimental data was simulated with different adsorption isotherms and kinetic
models to evaluate adsorption behavior of both dyes. Results confirmed that adsorption
of both the dyes followed Langmuir adsorption isotherm in case of GO-Ag and
Freundlich isotherm in case of GO-Au nanocomposite. Also, pseudo 2nd order kinetic
model was found to be favorable in case of all nanocomposites. Moreover, adsorbent
could be well regenerated in a suitable media for both dyes without any loss in removal
efficiency. The catalytic performance for the reduction of 2-nitroaniline (2-NA) has
been investigated in detail using GO-Au and GO-Ag nanocatalysts. Most importantly,
nanocomposites under study showed simultaneous adsorption of cationic and anionic
dyes from water and simultaneous catalytic reduction of a mixture of dyes (MG, MO,
and EV) and 2-NA. Additional advantages of prepared nanocomposite were their
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antibacterial activities due to the presence of different metal/metal sulphide
nanoparticles. Two bacterial strains (Gram-negative bacterium, E. coli and the Grampositive
bacterium, S. aureus) were used to test antibacterial activity of composite and
the results confirmed the remarkable performance of the nanocomposites in destroying
harmful pathogens. So, considering the facile synthesis process and the multiple
functions of all the nanocomposites, this work opens up a tremendous opportunity to
use GO based nanocomposites in wastewater treatment and nanomedicines. Also, this
work opens up a tremendous opportunity to bring GO based nanocomposites from
experimental research to practically applied materials for wastewater treatment