Nanoparticles possess
several properties, such as antimicrobial,
anti-inflammatory, wound healing, catalytic, magnetic, optical, and
electronic properties, that have allowed them to be used in different
fields. Among them, zinc oxide (ZnO) has received copious consideration
due to its technological and medicinal applications. Plant-mediated
synthesis of ZnO nanoparticles has provided a cost-effective and eco-friendly
method. Therefore, the objective of the study is to assess the effect
of the precursor concentration and silver and cerium doping on the
optical properties of ZnO nanoparticles synthesized via a green process
using bush tea leaf extract as the chelating agent. Zinc nitrate hexahydrate
was used as the precursor. Quasi-spherical-shaped ZnO nanoparticles
were obtained with an average crystallite size ranging between 24.53
and 63.02 nm. The crystallite size was found to decrease with the
increase of precursor concentration at 43.82 nm (0.05 g), 37.25 nm
(0.10 g), 26.53 nm (0.50 g), and 24.53 nm (1 g); thereafter, the size
increases with an increase in precursor concentration. The optimum
precursor concentration was 1 g with the smallest grain size and a
high purity level. The increase in annealing temperature induced an
increase in the crystallite size of ZnO nanoparticles from 24.53 nm
(600 °C) to 34.24 nm (800 °C), however, increasing the level
of purity of the nanopowders. The band gap energies were 2.75 and
3.17 eV as calculated using the Tauc plot with variations due to the
precursor concentrations. Doping with both silver and cerium increased
the band gap of ZnO nanoparticles up to 3.19 eV and the increase in
annealing temperature slightly augmented the band gap energy from
3.00 and 3.16 eV, respectively. Hence, doping with Ag and Ce induced
the formation of nanorods at higher concentrations. This study successfully
demonstrated that the natural plant extract of bush tea can be used
in the bioreduction of zinc nitrate hexahydrate to prepare pure ZnO
nanoparticles, thus extending the use of this plant to the nano producing
industry.
This study was undertaken to evaluate the potential future use of three biological processes in order to designate the most desired solution for on-site treatment of wastewater from residential complexes, that is, conventional activated sludge process (CASP), moving-bed biofilm reactor (MBBR), and packed-bed biofilm reactor (PBBR). Hydraulic retention time (HRT) of 6, 3, and 2 h can be achieved in CASP, MBBR, and PBBR, respectively. The PBBR dealt with a particular arrangement to prevent the restriction of oxygen transfer efficiency into the thick biofilms. The laboratory scale result revealed that the overall reduction of 87% COD, 92% BOD5, 82% TSS, 79% NH3-N, 43% PO4-P, 95% MPN, and 97% TVC at a HRT of 2 h was achieved in PBBR. The microflora present in the system was also estimated through the isolation, identification, and immobilization of the microorganisms with an index of COD elimination. The number of bacterial species examined on the nutrient agar medium was 22 and five bacterial species were documented to degrade the organic pollutants by reducing COD by more than 43%. This study illustrated that the present PBBR with a specific modified internal arrangement could be an ideal practice for promoting sustainable decentralization and therefore providing a low wastage sludge biomass concentration.
For the effective application of a modified packed bed biofilm reactor (PBBR) in wastewater industrial practice, it is essential to distinguish the tolerance of the system for heavy metals removal. The industrial contamination of wastewater from various sources (e.g. Zn, Cu, Cd and Ni) was studied to assess the impacts on a PBBR. This biological system was examined by evaluating the tolerance of different strengths of composite heavy metals at the optimum hydraulic retention time (HRT) of 2 hours. The heavy metal content of the wastewater outlet stream was then compared to the source material. Different biomass concentrations in the reactor were assessed. The results show that the system can efficiently treat 20 (mg/l) concentrations of combined heavy metals at an optimum HRT condition (2 hours), while above this strength there should be a substantially negative impact on treatment efficiency. Average organic reduction, in terms of the chemical oxygen demand (COD) of the system, is reduced above the tolerance limits for heavy metals as mentioned above. The PBBR biological system, in the presence of high surface area carrier media and a high microbial population to the tune of 10 000 (mg/l), is capable of removing the industrial contamination in wastewater.
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