Abstract
Low-cost nitrogen sources, i.e., dried spent yeast (DSY), rice bran (RB), soybean meal (SM), urea and ammonium sulfate were used for batch butanol fermentation from sugarcane molasses by Clostridium beijerinckii TISTR 1461 under anaerobic conditions. Among these five low-cost nitrogen sources, DSY at 1.53 g/L (nitrogen content equal to that of 1 g/L of yeast extract) was found to be the most suitable. At an initial sugar level of 60 g/L, the maximum butanol concentration (PB), productivity (QB) and yield (YB/S) were 11.19 g/L, 0.23 g/L·h and 0.31 g/g, respectively. To improve the butanol production, the concentrations of initial sugar, DSY and calcium carbonate were varied using response surface methodology (RSM) based on Box–Behnken design. It was found that the optimal conditions for high butanol production were initial sugar, 50 g/L; DSY, 6 g/L and calcium carbonate, 6.6 g/L. Under these conditions, the highest experimental PB, QB and YB/S values were 11.38 g/L, 0.32 g/L·h and 0.40 g/g, respectively with 50% sugar consumption (SC). The PB with neither DSY nor CaCO3 was only 8.53 g/L. When an in situ gas stripping system was connected to the fermenter to remove butanol produced during the fermentation, the PB was increased to 15.33 g/L, whereas the YB/S (0.39 g/g) was not changed. However, the QB was decreased to 0.21 g/L·h with 75% SC.
Highlights
Interest in liquid biofuel production continues to grow
It was found that the PB, QB and YB/S values from sugarcane molasses under the optimal condition were slightly higher than those using P2 medium (Table 7). These results suggested that sugarcane molasses with a low cost nitrogen source (DSY) is a suitable substrate for butanol production
Sugarcane molasses can be effectively used for butanol production
Summary
Interest in liquid biofuel production continues to grow. Ethanol is the most prominent of the renewable liquid biofuels, even with its drawbacks, i.e., lower energy content than gasoline, blending limitations with gasoline, and the need for corrosion resistant containers and pipes. The current pipeline infrastructure cannot be used to transport ethanol because of corrosion issues [1]. The acetone-butanol-ethanol (ABE) fermentation process is the most useful for production of fuels and chemicals from renewable resources. Butanol is superior to other fermentation derived fuels, including ethanol [2]. It has a lower vapor pressure than ethanol making it less flammable, safer to transport, and safer to use in combustion engines than ethanol [3]
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