Abstract
The composition of volatile fatty acids in the biogas digester based on cattle manure as substrate and stabilised at 25°C showed that it contained 87–88% branched chain fatty acids, comprising of isobutyric and isovaleric acids, in comparison to 38 % observed in the digester operating at 35°C.
Mixed cellulolytic cultures equilibrated at 25°C (C-25) and 35‡C (C-35) showed similar properties, but rates of hydrolysis were three times higher than that observed in a standard biogas digester. The proportion of isobutyric and isovaleric were drastically reduced when C-25 was grown with glucose or filter paper as substrates. The volatile fatty acids recovered from C-25 (at 25°C) inhibited growth of methanogens on acetate, whereas that from C-35 was not inhibitory. The inhibitory effects were due to the branched chain fatty acids and were observed with isobutyric acid at concentrations as low as 50 ppm.
Addition of another micro-organismRhodotorula selected for growth on isobutyric completely reversed this inhibition. Results indicate that the aceticlastic methanogens are very sensitive to inhibition by branched chain fatty acids and reduction in methane formation in biogas digester at lower temperature may be due to this effect.
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Abbreviations
- VFA:
-
volatile fatty acids
- IBA:
-
isobutyric acid
- IVA:
-
isovaleric acid
- TVM:
-
total volatilematter
- TS:
-
total solids
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Kalle, G.P., Menon, K.K.G. Inhibition of methanogenesis and its reversal during biogas formation from cattle manure. J Biosci 6, 315–324 (1984). https://doi.org/10.1007/BF02716746
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DOI: https://doi.org/10.1007/BF02716746