202
13 Biosorption of Heavy Metals and Metal-Complexed Dyes Under the Influence
complex adsorbed by the sawdust was 25.1 and 62.5 mg of dye per gram with respect
to metal complexed blue (MCB) and metal complexed blue (MCY). Additionally,
there is a possibility of intraparticle diffusion because of the movement of adsorbed
molecules through the porous medium present in the sawdust. The adsorption
density of sawdust reduces with increased adsorbent dose and due to the presence
of unsaturated adsorption active sites on the surface of the sawdust [40]. Erden et al.
carried out an experiment for the removal of Siris blue KFCN dye by the lyophilized
Trametes versicolor biomass. The obtained results revealed that the maximum
adsorption capacity of the respective biomass is around 62.62 mg/g. The kinetic and
the equilibrium data show that the adsorption process followed the pseudo-second
model and Langmuir isotherm model. It is stated that the biosorption followed the
biomass concentration and time. Additionally, the Langmuir adsorption defined
that the process followed monolayer coverage of adsorption. This biosorption
process depicted that the biomass is more effective than the well-known adsorbents
such as activated carbon and amberlite. Likewise, the potential of Aspergillus
parasiticus for the decolorization of textile reactive dye was tested by varying
various parameters such as ionic strength, reaction time, biomass concentration,
and initial metal concentration in batch studies. The obtained results showed that
the highest adsorption capacity achieved by the biomass is around 1.03 × 10−4 mol/g
at pH 2.0 with 2.0 g/l of biosorbent concentration. Additionally, the recent studies
showed that the material like fly ash shows a noteworthy effect on the removal
of several dyes such as methylene blue, rhodamine B, and malachite green from
the artificial textile wastewater. The obtained result delineated that the removal
of malachite green, rhodamine B, and methylene blue by the selective microbial
species is around 0.228–0.814, 0.184–0.618, and 0.219–0.644 mg/1, respectively,
when the initial dye concentration increased from 5 to 38 mg/l. The maximum time
taken to remove malachite green and rhodamine was around 80 minutes and it was
100 minutes for the methylene blue. Additionally, the Brewer spent grain (BSG)
was used as a material for the removal of Acid green (AG 25) by varying different
parameters such as initial pH, temperature, initial dye concentration, biosorbent
dosage, and contact time. The maximum amount of dye was adsorbed by the
biomass at pH 7 and 30 ∘C, the initial concentration was around 90 mg/l, and the
biomass concentration and time were found to be 0.2 g and 75 minutes, respectively.
The observed result depicted that the amount of dye removed increased with respect
to time and biomass concentration and decreased with respect to the temperature.
In the case of isotherm study, the equilibrium sorption capacity increased when
the initial dye concentration increased till 90 mg/l. Later, the adsorption capacity
was decreased due to the less availability of active sites. Likewise, the ability of
adsorption capacity of Ganoderma lucidum was tested with dyes present in the
wastewater by varying different parameters in response surface methodology. From
the results, the optimized conditions are observed at acidic pH of 6.6, temperature
of 26.5 ∘C, agitation speed of 200 rpm, and dye to wastewater ratio of 1 : 2. Under
these optimized conditions, the maximum dye decolorized is 81.4% and chemical
oxidation demand (COD) reduction is about 90.3%.