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Production of fuel alcohol from oats by fermentation

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Journal of Industrial Microbiology

Abstract

Very high gravity (>30 g dissolved solids per 100 ml) mashes were prepared from hulled and hulless oats and fermented at 20° C with active dry yeast to produce ethanol. Excessive viscosity development during mashing was prevented by hydrolyzing β-glucan with crude preparations of ‘σ-glucanase’ or ‘Biocellulase’. Both these preparations possessed endo-β-glucanase activity. By using these enzymes and by decreasing the water to grain ratio, very high gravity mashes with low viscosity were prepared. Unlike wheat and barley mashes, oat mashes contained sufficient amounts of assimilable nitrogen to promote a fast rate of fermentation. The free amino nitrogen (FAN) content of oat mash could be predicted by the equation, mg FAN L−1=8.9n wheren is the number of grams of dissolved solids in 100 ml of mash supernatant fluid. Ethanol yields of 353.2±3.7 L and 317.6±1.3 L were obtained per tonne (dry weight basis) of hulless (59.8% starch) and hulled (50.8% starch) oats respectively. The efficiency of conversion of starch to ethanol was the same in normal and very high gravity mashes.

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Thomas, K.C., Ingledew, W.M. Production of fuel alcohol from oats by fermentation. Journal of Industrial Microbiology 15, 125–130 (1995). https://doi.org/10.1007/BF01569812

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  • DOI: https://doi.org/10.1007/BF01569812

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