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Like world Pakistan is facing two major threats i.e. environment and energy.
Rapid industrialization and urbanization have resulted in elevated emission of toxic heavy
metals entering the biosphere. Activities such as mining and agriculture have polluted
extensive areas throughout the world. The release of heavy metals in biologically
available forms by human activities may damage or alter both natural and man-made
ecosystems. Heavy metal ions such as Pb 2+ , Cr 6+ , Cd 2+ Cu 2+ , Zn +2 and Ni +2 , are essential
micronutrients for plant’s and animal’s metabolism but when present in excess, can
become extremely toxic. Among the renewable energy technologies, solar energy, wind
energy, biofuels and biomass conversion occupy the central stage. The current study
belongs to biomass conversion to biofuels. It was focused on metal phytoremediation and
biofuel production from water hyacinth by using Nanobiotechnology.
Soil experiments show the phytoremoval of Pb 2+ , Cr 6+ , Cd 2+ Cu 2+ , Zn +2+ and Ni 2+
in μg/g of plant’s dry weight. Increase or decrease in pH and fresh weight is also
discussed. Lead, chromium, cadmium, copper, zinc and nickel showed phytoremoval of
27.91, 38.67, 1.915, 3.38, 13.11 and 24.23 μg/g of plant’s dry weight respectively.
Similarly phytoremoval of lead, chromium, cadmium, copper, zinc and nickel in kg/ha is
1582.45, 1053.38, 2852.75, 232.99, 1521.08 and 3449.76 respectively.
Hoagland’s hydroponic experiments show the phytoremoval of Pb 2+ , Cr 6+ , Cd 2+
Cu 2+ , Zn +2+ and Ni 2+ in μg/g of plant’s dry weight. Increase or decrease in pH and fresh
weight is also discussed. Lead, chromium, cadmium, copper, zinc and nickel showed
phytoremoval 19.132, 2.369, 8.888, 4.085, 0.845 and 1.954 μg/g of plant’s dry weight.
Adsorption and desorption experiments show phytoremoval (adsorption) of Pb 2+ ,
Cr 6+ , Cd 2+ Cu 2+ , Zn +2+ and Ni 2+ in μg/g of plant’s ash. While desorption (recovery for
reuse) of lead, chromium, cadmium, copper, zinc and nickel in μg/g of plant’s ash.
Adsorption capacity is 29.83, 24, 28.41, 29.83, 29.94 and 29.79 μg/g of plant’s ash
respectively. The biosorptive capacity is highest with pH > 8.00. The desorption capacity
of lead, chromium, cadmium, copper, zinc and nickel is 18.10, 9.99, 27.54, 21.09, 11.99,
3.71 μg/g of plant’s ash respectively.
Bioanalytical experiments were performed to assess the metallic concentrations of
Taxilian water hyacinth. Some selected microbes from hyacinth’s roots were isolated,
xxidentified by biochemical tests and purified by microbiological experiments. Our results
show that Thiobacillus thiooxidans, Thiobacillus ferrooxidans, Azotobacter and A. niger
are present in the roots of water hyacinth. Thiobacillus thiooxidans, Thiobacillus
ferrooxidans and A. niger are commonly well known for metal’s bioremediation. Their
presence in the roots of water hyacinth show that these microbes may have some role in
metal’s phytoremediation by hyacinth. Azotobacter is generally nitrogen fixing bacteria its
presence may shows relationship with nitrogen’s phytoremoval by hyacinth. The presence
of Mn, Mo, Fe, Cr and some other metals in nitrogenase enzymes of Azotobacter, is
already documented. Therefore Azotobacter’s presence may also be responsible for
phytoremoval of these metals by water hyacinth.
Three different studies were performed for the nanobiotechnological conversion of
water hyacinth (Eichhornia crassipes) plant into biofuel. In the first study water hyacinth
was saccharified with diluted sulfuric acid (1% v/v at 110 o C for one hour) and fermented
by yeast (Saccharomyces cerevisiae). The results show the formation of 55.20 % ethanol
and 41.66 % acetic acid. In another experiment water hyacinth was gasified by using Ni
and Co nano catalysts at 50-400oC and atmospheric pressure. In catalytic gasification
methane (2.41-6.67%), ethene (19.74-45.52%), propyne (21.04-45.52%), methanol (1.43-
24.67%), and propane/acetaldehyde (0.33-26.09%) products are obtained. In third study
anatase form of titanium dioxide photocatalyst was used. The reaction was performed at
room temperature which gives good percentage of methane (53.19%), methanol (37.23%)
and ethanol (9.57%). This study reports an interesting finding that metal contaminated
water hyacinth could be used for not only the production of biofuel but also hydrocarbons
Present study gives solution of two major problems of the world i.e.
environmental pollution and fuel. It also shows comparison of three different
phytoremediation technologies and use of water hyacinth as a metal hyper accumulator
and a source of hydrocarbon gases and bioethanol. These technologies are cheap and may
be developed further for commercial use. |
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