Environmental pollution caused by h

Environmental pollution caused by heavy metals is deteriorating
the environment and endangering human health. This has
become a serious problem due to the toxic properties of heavy
metals and their tendency to bio-accumulate in the food chain [1].
The presence of heavy metals in the aquatic environment is a major
concern due to their extreme toxicity. Heavy metals from
wastewater are commonly removed by chemical precipitation,
ion-exchange, membrane separation, reverse osmosis, and activated
carbon (AC) adsorption [2,3]. Adsorption has attracted much
attention as an effective purification and separation technique for
treating wastewater, and removing heavy metals from wastewater
is an important application of adsorption processes using a suitable
adsorbent [3,4]. Various adsorbents such as AC, iron oxides,
filamentous fungal biomass, zeolite, and chitosan have been
applied to remove heavy metals from wastewater. AC is generally
recognized as an effective adsorbent due to its high porosity, large
surface area, and high catalytic activity and is currently widely
used to remove organic compounds [5]. However, AC has a
relatively low adsorption capacity for inorganic pollutants
compared to organic pollutants and requires longer time to
remove contaminants [6,7].
Modifying AC with suitable additives has been investigated to
enhance its adsorption efficacy [8]. Modified activated carbon
studied includes palladium, silver, copper sulphide and zinc oxide
nanoparticle loaded activated carbon [7,9,10]. Even though a
number of works were done on the sorption of metals and organic
contaminants using modified activated carbon, there are few
researches on the adsorption of heavy metals by manganese oxide
loaded activated carbon because Mn3O4 is regarded as a new
adsorbent [11]. Manganese oxides are a very important scavenger
of aqueous trace metals in soil, sediments, and rock because of
their dominant sorptive behavior [12]. Therefore, several studies
have been conducted using manganese oxide-coated adsorbents to
enhance adsorption capacity from aqueous solutions by using their
high affinity for heavy metals [13–16]. In previous heavy metal
removal studies, chemical precipitation methods were used to coat
manganese oxide onto an adsorbent support, and the major form of
manganese oxide was manganese dioxide (MnO2). However,
various active states of manganese and particle dispersion can
be obtained using different precursors and preparation methods,
which influence activity of the catalysts. Calcination temperature
determines the final oxidation state of the supported manganese