dc.description.abstract |
Biomethane being a mixture of gases a possible solution for the energy
crisis worldwide. The biomethane comes from anaerobic digestion (AD) process
that can be run with the widely available lignocellulosic biomass like agricultural
and municipal waste which otherwise would have been wasted in raw. In the past,
the common usage of manure was to be applied as a fertilizer, which can have an
adverse environmental impact in terms of terrestrial eutrophication and emission of
greenhouse gases. These days, a solution applied for wastes and residues is to treat
them with the simultaneous recovery of energy through anaerobic digestion (AD).
The present study was designed to increase the methane production by using codigestion
and photo-catalytic oxidation with aim to increase the methane
production by synergism/biodegradability and lignin oxidation respectively. In the
first step, the substrates were separately analyzed for mono-digestion where wheat
straw (WS) produced 255 mLCH4/gVS, meadow grass (MG) produced 301
mLCH4/gVS and cattle manure (CM) produced 307 mLCH4/gVS. Furthermore, the
co-digestion results revealed a maximum of 25 per cent increase in methane
production which had a significance level of p<0.05 over mono-digestion of cattle
manure (CM), when 25 per cent of the manure contents were replaced with
lignocellulosic biomass. The over-all biodegradation of the above mentioned
combination also reached to 84 per cent in co-digestion from 67 per cent in monodigestion.
In the second step the wheat straw (WS) which produced least methane
in mono-digestion experiments was subjected to photo-catalytic oxidation with
titanium oxide TiO2 and ultraviolet light of 200-400 nm (UV). Specifically, four
different TiO2 concentrations (0.0, 0.5, 1.0, 1.5, and 2.0 per cent (w/w) were tested
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at three different irradiation times (0, 1, 2, and 3 hours). Among the products from
the oxidative degradation of lignin under TiO2/UV catalyst system, vanillic acid
and ferulic acid were detected at a maximum value of 91.18±2.00 mg/L and
1.67±0.01 mg/L, using 2.0 per cent (w/w) TiO2 for 3 hours. Moreover, the most
effective pretreatment strategy (1.5 per cent (w/w) TiO2 and 3 hours) was found to
increase the biodegradability of wheat straw up to 37 per cent compared to
untreated biomass. The positive impact of photo-catalytic pretreatment was also
observed in continuous trials, when methane production was increased by 25 per
cent. The photo-catalytic oxidation of lignin-rich substrates is a promising method
to disrupt the non degradable organic fraction under mild conditions. It is expected
that thorough study of this process can still increase methane production to many
folds at industrial scale. Not only high methane yield but also the direct conversion
of lignocellulosic biomass can be attained e.g vanillic and ferulic acid. Therefore, it
is also expected that application of this methodology for production of biomethane
in future will not only help to overcome shortfall of energy but also will provide
environmental benefits |
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