Biohydrogen production from cattle wastewater by enriched anaerobic mixed consortia: influence of fermentation temperature and pH. J. Biosci. Bioeng. 106(1), 80-87

College of Resources and Environmental Sciences, China Agricultural University, Beijing 100094, PR China.
Journal of Bioscience and Bioengineering (Impact Factor: 1.79). 08/2008; 106(1):80-7. DOI: 10.1263/jbb.106.80
Source: PubMed

ABSTRACT Experiments were conducted to select a natural mixed microflora seed source and investigate the effect of temperature and pH on fermentative hydrogen (H2) production from cattle wastewater by sewage sludge. Sewage sludge was shown to have higher cumulative H2 production than other inoculum collected from cow dung compost, chicken manure compost, and river sludge. Experimental results show that H2 production from cattle wastewater was significantly affected by both pH and temperature of the culture. The maximum H2 yield was obtained at pH 5.5. H2 yield and the ratio of butyrate/acetate (Bu/Ac) followed a similar production trend, suggesting that butyrate formation might favor H2 production. The optimal temperature for H2 production from cattle wastewater was 45 degrees C with peak values of H2 production (368 ml), hydrogen yield of 319 ml H2/g chemical oxygen demand (COD) consumed, and butyrate/acetate ratio of 1.43. Presence of ethanol and propionic acid indicated decreased hydrogen production; their concentrations were also affected by pH and temperature. A modified Gompertz model adequately described H2 production and bacterial growth.

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    • "To overcome the stated problems, farmers apply fertilizers excessively to attain higher yield. However, unbalanced use of N and P fertilizers causes environmental problems such as eutrophication , groundwater pollution, acid rain deposition, soil acidification, and greenhouse gas emissions [9] [10] [11] [12]. "
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    01/2015; 2015:1-14. DOI:10.1155/2015/906094
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    • "However, there was little information on hydrogen production from OPEFB biomass hydrolyzate which is composed mainly of simple carbohydrate. Typically, the fermentation of biomass hydrolyzate, that uses wastewater sludge as inoculums, is influenced by parameters such as pH, temperature and substrate specificity [38]. The perception of the hydrogen production under different operational condition is extraordinarily narrowed, particularly with the use of mixed culture. "
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    ABSTRACT: a b s t r a c t Carbohydrates from hydrolyzed biomass has been a potential feedstock for fermentative hydrogen production. In this study, oil palm empty fruit bunch (OPEFB) was treated by sulfuric acid in different concentrations at 120 C for 15 min in the autoclave. The optimal condition for pretreatment was obtained when OPEFB was hydrolyzing at 6% (w/v) sulfuric acid concentration, which gave the highest total sugar of 26.89 g/L and 78.51% of sugar production yield. However, the best conversion efficiency of OPEFB pretreatment was 39.47 at sulfuric acid concentration of 4%. A series of batch fermentation were performed to determine the effect of pH in fermentation media and the potential of this prehydrolysate was used as a substrate for fermentative hydrogen production under optimum pretreat-ment conditions. The prehydrolysate of OPEFB was efficiently converted to hydrogen via fermentation by acclimatized mixed consortia. The maximum hydrogen production was 690 mL H 2 L À1 medium, which corresponded to the yield of 1.98 molH 2 /mol xylose achieved at pH 5.5 with initial total sugar concentration of 5 g/L. Therefore, the results implied that OPEFB prehydrolysate is prospective substrate for efficient fermentative hydrogen con-ducted at low controlled pH. No methane gas was detected throughout the fermentation.
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    • "(g COD/L) pH Temp. ( C) HRT (h) HY (mol H 2 /mol hexose) HPR (L/L/d) References Range studied Optimal Range studied Optimal Range studied Optimal Range studied Optimal Apple processing wastewater Batch Soil 9 e 6.1 e 23 e e e 4.08 mmol/g COD 2.16 [4] Brewery wastewater Batch AS 2e12 6.05 4e8 5.95 25e45 36 e e 6.11 mmol/g COD 8.58 [26] Cattle wastewater Batch SS 1.324 e 4.5e7.5 5.5 30e55 45 e e 12.41 mmol/g COD 0.34 [44] Cereal wastewater Batch AS 8.92 e 6.0 e 30 e e e 0.24 e [7] Chemical wastewater and domestic sewage wastewater Batch AM 2.75 e 6.0 i e 29 e e e 1.25 mmol/g COD e [45] "
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    ABSTRACT: a b s t r a c t Biohydrogen is a promising candidate which can replace a part of our fossil fuels need in day-to-day life due its perceived environmental benefits and availability through dark fermentation of organic substrates. Moreover, advances in biohydrogen production tech-nologies based on organic wastewater conversion could solve the issues related to food security, climate change, energy security and clean development in the future. An evalu-ation of studies reported on biohydrogen production from different wastewaters will be of immense importance in economizing production technologies. Here we have reviewed biohydrogen production yields and rates from different wastewaters using sludges and microbial consortiums and evaluated the feasibility of biohydrogen production from unexplored wastewaters and development of integrated bioenergy process. Biohydrogen production has been observed in the range of substrate concentration 0.25e160 g COD/L, pH 4e8, temperature 23e60 C, HRT 0.5e72 h with various types of reactor configuration. The most efficient hydrogen production has been obtained at an organic loading rate (OLR) 320 g COD/L/d, substrate concentration 40 g COD/L, HRT 3 h, pH 5.5e6.0, temperature 35 C in a continuously-stirred tank reactor system using mixed cultures and fed with condensed molasses fermentation soluble wastewater. The net energy efficiency analysis showed vinasse wastewater has the highest positive net energy gain followed by glycerin waste-water and domestic sewage as 140.39, 68.65, 51.84 kJ/g COD feedstock with the hydrogen yield (HY) of 10 mmol/g COD respectively.
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