Environmental Engineering Reference
In-Depth Information
processes where both hydrogen and methane can be produced from a range of dif-
ferent feedstocks. Therefore, two-stage anaerobic fermentation may potentially lead
to higher energy recoveries and further research efforts should be directed to ensure
process efficiency and stability.
References
Chu, C., E. Yoshitaka, K. Xu, Y. Li, and Y. Inamori. 2010. Characterization of microbial community
in the two-stage process for hydrogen and methane production from food waste.
International
Journal of Hydrogen Energy
35 (15): 8253-8261.
Gadow, S., Y. Li, and Y. Liu, 2012. Effect of temperature on continuous hydrogen production of
cellulose.
International Journal of Hydrogen Energy
37 (20): 15465-15472.
Gadow, S., H. Jiang, T. Hojo, and Y. Li. 2013. Cellulosic hydrogen production and micro-
bial community characterization in hyper-thermophilic continuous bioreactor.
International
Journal of Hydrogen Energy
38 (18): 7259-7267.
JARRRS. 2014. Japan Association of Rural Resource Recycling Solutions. Reference system
for information of biomass technology.
http://www2.jarus.or.jp/biomassdb/
(in Japanese)
Accessed 10 Aug 2014.
Karnayakage R., B. Perera, A. Yalini, and N. Nagamany. 2012. Fermentative biohydrogen
production II: Net energy gain from organic wastes.
International Journal of Hydrogen Energy
37 (17): 167-178.
Kobayashi, T., K. Xu, Y. Li, and Y. Inamori. 2012. Effect of sludge recirculation on characteristics
of hydrogen production in a two-stage hydrogen-methane fermentation process treating food
wastes.
International Journal of Hydrogen Energy
37 (7): 5602-5611.
Leith, H., and R. Whittaker, eds. 1975.
Primary productivity of the biosphere
. New York: Springer-
Verlag.
Li, Y., and O. Nishimura. 2007. Recycle of waste biomass by methane fermentation technology.
Japanese Journal of Multiphase flow
21 (1): 29-38.
Niu, Q., W. Qiao, H. Qiang, T. Hojo, and Y. Li. 2013. Mesophilic methane fermentation of
chicken manure at a wide range of ammonia concentration: Stability, inhibition and recovery.
Bioresource Technology
137:358-367.
Niu, Q., T. Hojo, W. Qiao, H. Qiang, and Y. Li. 2014. Characterization of methanogenesis, acido-
genesis and hydrolysis in thermophilic methane fermentation of chicken manure.
Chemical
Engineering Journal
244:587-596.
Ogawa, Y., M. Fujita, and Y. Nakagawa. 2005. Comparison between mesophilic and thermophilic
methane fermentation treatments of manure and food waste.
Journal of Japan Society Waste
Management Experts
16 (1): 44-54 (in Japanese).
Qiao, W., K. Takayanagi, Q. Niu, M. Shofie, and Y. Li. 2013. Long-term stability of thermophilic
co-digestion submerged anaerobic membrane reactor encountering high organic loading rate,
persistent propionate and detectable hydrogen in biogas.
Bioresource Technology
149:92-102.
Reith, J., R. Wijffels, and H. Barten. 2003.
Bio-methane and bio-hydrogen: Status and perspectives
of biological methane and hydrogen production
. Netherlands: Dutch Biological Hydrogen
Foundation.
