dc.description.abstract |
Waste management is one of the most serious concerns faced worldwide today. The
management of wastewater released from the various industries contains hazardous
organic pollutants (as classified by USEPA). It causes various adverse effects on the
human and the environment. Therefore, it is imperative to develop efficient,
economical and sustainable technique for the degradation of these hazardous organic
pollutants. In this regard, bioremediation and photo-catalytic degradation have been
proposed as the most favorable and sustainable techniques. Bibliometric analysis has
shown that research communities are increasingly focusing on these two techniques of
organic pollutant degradation from wastewater. Bioremediation practice has proved to
be a huge success in the laboratory and also in many cases, in the natural
environment. Most of the studies done on bioremediation of petrochemical waste
employed bacteria for the degradation purpose owing to its very fast growth and easy
adaptation in changing environmental conditions. Therefore, environmental
microbiologists and biotechnologists have the challenging objective of solving these
problems using microorganisms in bioremediation technologies. Biological methods
have low operating costs and involve direct degradation of organic pollutants, without
release of the toxic intermediates. However, the selection of microorganisms is
critical factors in efficient degradation of petrochemical waste. To overcome the
drawbacks of bioremediation, photo-catalysis can be considered as one of the most
promising techniques. It is a viable alternative for efficient degradation of monocyclic
and polycyclic petrochemical wastes. Literature survey revealed that the emerging
trends in the photodegradation of organic pollutants among all used semiconductors
TiO2 is widely reported in the degradation processes along with other semiconductors/
nano-materials in visible and UV light irradiation. This advance oxidation processes (AOPs) is evolving techniques for efficient sequestration of chemically stable and less
biodegradable organic pollutants. However, there is need to develop more effective
method, which consumes less energy and more efficient in pilot scale for the
mineralization of pollutant. Photocatalytic processes are a viable alternative for
efficient degradation of monocyclic and polycyclic petrochemical wastes and solve
the problem of transformation from one form to another. The uses of alternative light
sources such as LEDs are promising for reduction in power consumption. There is
need to develop more efficient techniques in which solar energy are used for
photocatalysis process. Presently only 5% of solar radiation are used for catalysis
processes. However, there are various drawbacks associated with photocatalytic
degradation such as high energy consumption and capital cost associated with
photodegradation process. Toxic intermediates produced during photo-catalytic
degradation are more toxic than the pollutants to various environments. It limits the
wider adaptability of photo-degradation pathways.
The shortcomings in the present condition of the abovementioned techniques
lead to their limited application. It includes low efficiency, high running cost, skilled
man-power requirement, microbial specificity to pollutants and sensitivity to various
environmental factor, which have limited their wider adaptability.
Therefore, efforts are being done for the technological development and in
adopting various improved biological and photo-catalytic methods in the wastewater
management. Therefore, in the present study, we evaluated the and photo-catalytic
degradation processes for the efficient wastewater management technique. For
biodegradation processes, various microbes were isolated from the contaminated sites and used in the batch reactor for the degradation study of benzene and toluene.
However, photo-catalytic degradation study was done by synthesis and
characterization of Activated carbon based TiO2 composite for degradation two dye
compounds.
In the present study deals with biodegradation aspect of organic pollutants, in
which various microbes has been isolated for the degradation of toluene and benzene
from sites contaminated from petrochemical waste. These compounds are the priority
pollutants, which adversely affects the human health and the environment. Among the
isolated microbes, potential microbes were selected for biodegradation of toluene and
benzene. The culture labeled as CH005 was very much close to Acinetobacter junii
isolate OTU-a6 (GenBank Accession Number: KJ147060.1) based on nucleotide
homology and phylogenetic analysis. Culture labelled as CH007 was identified as
Serratia marcescens strain 35 dr (GenBank Accession Number: KJ729606.1) while
CH010 was identified as Klebsiella pneumoniae strain GX120222 (GenBank
Accession Number: KP091888.1). List of some other organisms along with their
accession numbers, that have been used for degradation of toluene and benzene are
included in chapter 4.
The parameters were optimized at which these microbial strains were showing
maximum biodegradation of benzene and toluene. The pH is one of the most
important factor controlling the growth and enzymatic activities of the
microorganisms. In our study, pH 4.5 to 9.5 was selected to observe the toluene
degradation efficiency of selected bacterial strains. We observed an enhancement in
the percent degradation by mixed culture with an increase in pH from 6.5 to 7.5. However, a reduction in degradation activity was observed beyond pH 7.5 due to
lowered enzymatic activity. At pH 4.0, 6.5, 7.5, 8.5 and 9.5 toluene degradation by
mixed culture was 12%, 48%, 52%, 46% and 30%, respectively. In the present study,
the bacterium demonstrated the highest biodegradation at pH 7.5. Thus, optimum pH
7.5 was selected for further degradation studies.
Majority of the studies on toluene biodegradation have been performed with
anaerobic microorganisms. In the present study, we evaluated the toluene degradation
ability under aerobic conditions. With an increase in time gap, concomitant increase
in percent degradation by both single and mixed culture was observed. Pure culture of
Acinetobacter junii was able to degrade 69, 73 and 80% of 150, 100, and 50 ppm of
toluene concentrations, respectively within 72 hours. The pure culture of Serratia
marcescens was able to degrade 74, 77, and 82% of 150, 100, and 50 ppm of toluene
concentration within 72 hours. However, Klebsiella pneuminae degraded 65, 79, and
89% of 150, 100, and 50 ppm of toluene concentration, respectively within 72 hours.
It indicates that Serratia marcescens was the most effective amongst all the tested
pure cultures, as they were able to degrade 74% of 150 ppm toluene. Moreover, we
observed that 80% of toluene was degraded within 72 hours by the mixed bacterial
culture. This might be attributed to the broad enzymatic capability of the consortium,
which enhances the rate of degradation. Toluene degradation with time in the present
study shows that the degradation occurs due to the enzymatic activities resulting from
bacterial growth. The percent removal was very low up to 72 hours, showing
saturation of enzymes involved in degradation. However, we selected 150 ppm
benzene concentration for biodegradation and evaluated the degradation performance
of mixed bacterial culture under optimum conditions. Benzene degradation by mixed culture in mineral salt media (MSM) was determined to be 63% within 72 hours of
incubation. It reached to saturation stage after 60 hours of incubation period. No
further degradation was observed up to 72 hours, probably due to cellular enzyme
saturation. Under optimum laboratory conditions, mixed culture of Acinetobacter
junii, Serratia marcescens and Klebsiella pneumoniae has proved to be the most
efficient bacterial strins in biodegradation in the present study. The present study will
be beneficial in the industrial level treatment using biological treatment technologies
We observed the degradation intermediates produced by use of these bacterial
strains. Toluene degradation by Acinetobacter junii isolate CH005 resulted in the
formation of intermediate compounds such as 1-Isopropenyl-4-methyl-1,3-
cyclohexadiene,1,3-Cyclohexadiene, 2-Methyl-5-(1-Methylethyl), 4-
Methoxycarbonyl-4-butanolide Vinyl (2E,4E)-2,4-hexadienoate. However, benzene
degradation by mixed bacterial culture resulted into formation of different
compounds. The compounds produced were Phenol, 2,4, bis (1,1 dimethyl ethyl).
Benzene acetaldehyde, alpha methyl (Trigueros, 2010) and Gamma butyrolactone
These compounds are of general occurrence after aerobic bacterial degradation.
We also performed the morphological studies in our study to observe the
effect of organic pollutant and their degradation intermediates on the bacterial strains.
Surface morphology as revealed by SEM of the untreated and toluene treated
Acinetobacter junii, Klebsiella pneumonia, Serratia marcescens and mixed culture
showed that, all bacterial cells are cylindrical. However, some long cylindrical cells
were transformed into ovoid and spherical structure after treatment, probably to
escape themselves from toxicity. Bacterial systems have developed several types of changes at the biochemical and physiological level which makes them suitable to
survive under stressed conditions as observed in presence of organic compounds
including benzene, toluene, ethylbenzene and xylene. The protective mechanisms also
include changes in characteristics of cell membrane, alteration in cell shape, size,
formation of vesicular structure on membrane and protein associated with stress
tolerance, efflux pumps and energy pool maintenance.
In the present studies, the toluene and benzene biodegradation by bacteria
Acinetobacter junii, Serratia marcescens and Klebsiella pneumoniae was best at pH
7.5 and at a temperature of 37°C. Temperature ranging from 30 to 40 °C has been
used demonstrate the rate of hydrocarbon degradation. The bacterial species showed
varying degree of ability in toluene degradation. Furthermore, mixed bacterial culture
was found most suited for the degradation purpose with highest efficiency of
degradation. Moreover, it is necessary to support the activities of these indigenous
microorganisms by bioaugmentation and biostimulation in the polluted biotopes to
enhance their degradation abilities.
The present study seeks to offer a scientific and technical overview of the
current trend in the use of the photocatalyst for remediation and degradation of
petrochemical waste as reported in the recent studies. The effect of various
heterogeneous catalysts and their ecotoxicity has been briefly outlined. Also, the use
of various photocatalysts for the degradation of petrochemical waste other than TiO2
has been also azalysized. We performed the photocatalytic degradation of organic dye
in self fabricated photo rector. Three reactors were used during this experiment. A
photochemical reactor which consisted of a cylindrical reactor fitted in with 8 Phillips UV lamps of intensity 960 LUX along with a magnetic stirrer shows schematic view
of the photochemical reactor. For carrying out sonication reaction, a reactor fitted
with a Sonicator (Hielsher Ultrasound Technology) was used. Figure 3.1 shows a
schematic representation of a reactor consisting of a combined photo- and Sonocatalytic
reaction. All these reactors were provided with cooling jackets with water
flowing inside them so as to avoid overheating.
Various solutions consisting of different concentrations of dye, along TiO2/AC
catalyst was used for the photo-catalytic degradation experiment. The experiments
were conducted in the three batch reactors as shown earlier. The samples were taken
out from the batch reactor at fixed time interval and their concentration was measured.
This data was then used for further calculations. In present study, degradation analysis
of Direct Blue-199 and Acid Red-131 dyes was done following various photocatalytic
pathways. A catalyst, TiO2 loaded on Activated charcoal, was prepared in
the process and its characterizations was done, which showed an even distribution of
TiO2 (rutile phase) on the catalyst surface. The catalyst calcinations temperature was
also optimized, which was found to be 350 oC. A first order reaction kinetics was
then developed for the catalytic oxidation of dye using L-H model. The degradation of
DB-199, via photocatalytic, sonocatalytic and sono-photocatalytic reactions, under
optimized working conditions followed L-H model satisfactorily. These three reactors
used for the degradation of dye were tested on the basis of degradation rates and
energy consumption. Photo-catalytic reactor was found to be the best option amongst
all the reactors used. The contribution of intermediates formed during the reaction is
not considered in the kinetics study; however, there have been reports about the
competitive involvement of intermediate products during the photochemical process. The role of intermediates can be involved further for the development of reaction
kinetics model. After optimization of the reactor conditions and efficacy, degradation
reactions of dye (AR-131) were done in the photochemical reactor. The degradation
was found to follow a first order kinetics mechanism (vis. Langmuir-Hinshelwood
Model).
The release of these nano-materials into the environment has been reported to
affect the plant growth mechanisms and development from the seeds germination to
pollination. The understanding of the degree at which spent nano-particles affects seed
germination and plant development is also an important issue. Therefore, we observed
the effect of unused catalysts on environment after the photochemical degradation of
dye. It was observed through the impact of these unspent catalysts on the seed
germination of various plant species. The response of species to various composite
nano-materials depends on the concentration, nature, and size of nanoparticles, which
could have economic significance for agriculture. Various studies reported that the
intermediates or end products formed in the photo-catalytic degradation process are
sometimes more toxic than the original compounds. However, various studies have
also supported that it increases the production of various crops, and improves the
essential element content in plant tissue by increasing peroxidase, catalyse and nitrate
reductase activity in plant tissues and enhancing their chlorophyll. Therefore, besides
the advancement in the materials as the catalysts for degradation of persistent organic
pollutant from water and air, their eco-toxicity should also be considered. Therefore,
understanding of the mechanisms of interaction of nano-materials with the plants
species is required. In the present study, AC/TiO2 nano-composite had positive impacts on the germination of V. radiata and Solanum lycopersicon seeds. It can be attributed to the
fact that TiO2 was able to penetrate the seed husks of these seeds. It might be attributed
to the penetration of AC/TiO2 nano-composite into seeds, which might break the husks
to facilitate the water uptake, which resulted in the rapid seed germination and higher
percentage of germination rates. Moreover, at the stage of seedling growth, activated
carbon may also be providing the moisture. Compared to the control, enhanced
germination was found at increased concentration, however, the growth of root and
shoot of seedling either decreased or remained stable. It was observed that stems and
roots of the seedlings were longer than those of the control with higher concentration of
treatment. Carbon nano-materials are known for their abilities to enhance the seedling
growth and development. Effect of nanomaterials on the plant growth has been found to
depend upon the type of nano-materials, size-specific area, functional groups,
concentration, plant species, soil type and condition. AC/TiO2 nano-composite enhanced
the shoot and root ratio depending on concentration. It envisaged that the increase in root
and shoot ratio may be related to the concentration of catalysts; however, elaborative
physiological studies are needed for the better understanding of this mechanisms. These
results would help in mechanistic understanding of the interaction of nano-materials
with plants species in the environment.
With majority of treatment techniques having major drawback of generation of
another type of wastes, biodegradation and photocatalytic mineralization looks a very
promising techniques. Overall, I strongly believe that there is a need to scale up this
degradation technique from lab to land scale. For industrial wastewater treatment, there
is a need to develop hybrid processes of photo-degradation followed by biodegradation. The hybrid technique may be sustainable in all respect (economic as well as
environmental). There is a possibility to develop hybrid techniques based on these two
existing processes for more efficient degradation of organic pollutants
Recommendation:
We can make following recommendation based on the present study.
1. The need of the hour is to improve our understanding of the molecular
reactions which form the basis of bioremediation.
2. Development of hybrid pathways through genetic manipulation of
microorganisms is one of the promising techniques which would drastically
improve the process of bioremediation.
3. Photocatalytic degradation needs more research to make these processes more
efficient. Particularly, There is need to develop more efficient techniques in
which solar energy are used for photocatalysis process. Presently only 5% of
solar radiation are used for catalysis processes.
4. Another unexplored areas of the degradation of organic pollutant is to devise
and promote hybrid processes (based on both the bioremediations and
photocatalytic degradation routes) of two above-mentioned techniques.
Therefore, combined processes can be the most promising technology for the
remediation of environmental pollutant in future.
5. There is need of more research to understand the effect of nanoparticles on
soil microbiology and plant growth. |
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