Browse > Article
http://dx.doi.org/10.7745/KJSSF.2012.45.2.156

Recovery of Sustainable Renewable Energy from Marine Biomass  

Gurung, Anup (Department of Biological Environment, Kangwon National University)
Oh, Sang-Eun (Department of Biological Environment, Kangwon National University)
Publication Information
Korean Journal of Soil Science and Fertilizer / v.45, no.2, 2012 , pp. 156-161 More about this Journal
Abstract
Marine biomass is considered an important substrate for anaerobic digestion to recovery energy i.e. methane. Nevertheless, marine biomass has attracted little attention by researchers compared to terrestrial feedstock for anaerobic digestion. In this study, biochemical methane potential (BMP) test was used to evaluate generation of renewable energy from starfish. A cumulative biogas yield of $748{\pm}67mL\;g^{-1}VS^{-1}$ was obtained after 60 days of digestion. The cumulative methane yield of $486{\pm}28mL\;CH_4\;g^{-1}VS^{-1}$ was obtained after 60 days of digestion. The methane content of the biogas was approximately 70%. The calculated data applying the modified Gompertz equation for the cumulative $CH_4$ production showed good correlation with the experimental result obtained from this batch study. Since the result obtained from this study is comparable to results with other substrates, marine biomass can be co-digested with food waste or swine wastewater to produce $CH_4$ gas that will help to reduce the gap in global energy demand.
Keywords
Biogas; Co-digestion; Marine biomass; Renewable energy;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Agdag, O.N. and D.T. Sponza. 2005. Effect of alkalinity on the performance of a simulated landfill bioreactor digesting organic solid wastes. Chemosphere. 59:871-879.   DOI
2 Angelidaki, I., M. Alves, D. Bolzonella, L. Borzacconi, J.L. Campos, A.J. Guwy, S. Kalyuzhnyi, P. Jenicek, and J.B. Van Lier. 2009. Defining the biomethane potential (BMP) of solid organic wastes and energy crops: A proposed protocol for batch assays. Water Sci. Technol. 59:927-934.   DOI
3 APHA. 1998. Standard methods for the examination of water and wastewater.American Public Health Association: USA.
4 Bauen, A. 2006. Future energy sources and systems-Acting on climate change and energy security. J. Power Sources. 157:893-901.   DOI
5 Behera, S.K., J.M. Park, K.H. Kim, and H.S. Park. 2010. Methane production from food waste leachate in laboratory-scale simulated landfill. Waste Manage. 30:1502-1508.   DOI
6 Bird, K.T., D.P. Chynoweth, and D.E. Jerger. 1990. Effects of marine algal proximate composition on methane yields. J. Appl. Phycol. 2:207-213.   DOI
7 Chandra, R., V.K. Vijay, P.M.V. Subbarao, and T.K. Khura. 2012. Production of methane from anaerobic digestion of jatropha and pongamia oil cakes. Appl. Energy. 93:148-159.   DOI
8 Cho, J.K., S.C. Park. and H.N. Chang. 1995. Biochemical methane potential and solid state anaerobic digestion of Korean food wastes. Bioresour. Technol. 52:245-253.   DOI
9 Chynoweth, D.P., J.M. Owens, and R. Legrand. 2000. Renewable methane from anaerobic digestion of biomass. Renew. Energy. 22:1-8.
10 Ehimen, E.A., Z.F. Sun, C.G. Carrington, E.J. Birch, and J.J. Eaton-Rye. 2011. Anaerobic digestion of microalgae residues resulting from the biodiesel production process. Appl. Energy. 88:3454-3463.   DOI
11 Gompertz, B. 1825. On the Nature of the Function Expressive of the Law of Human Mortality, and on a New Mode of Determining the Value of Life Contingencies. Philos. T. Roy. Soc. Lon. 115:513-583.   DOI
12 Gunaseelan, V.N. 2004. Biochemical methane potential of fruits and vegetable solid waste feedstocks. Biomass Bioenergy. 26:389-399.   DOI
13 Hansen, T.L., J.E. Schmidt, I. Angelidaki, E. Marca, J.L.C. Jansen, H. Mosbaek, and T.H. Christensen. 2004. Method for determination of methane potentials of solid organic waste. Waste Manage. 24:393-400.   DOI
14 Heo, N.H., S.C. Park, and H. Kang. 2004. Effects of mixture ratio and hydraulic retention time on single-stage anaerobic co-digestion of food waste and waste activated sludge. J. Environ. Sci. Health A 39:1739-1756.   DOI   ScienceOn
15 IEA. 2011. Key world energy statistics. International Energy Agency: Paris.
16 Katuwal, H. and A.K. Bohara. 2009. Biogas: A promising renewable technology and its impact on rural households in Nepal. Renew. Sustain. Energy Rev. 13:2668-2674.   DOI
17 Kim, H.W., S.K. Han, and H.S. Shin. 2003. The optimization of food waste addition as a co-substrate in anaerobic digestion of sewage sludge. Waste Manage. Res. 21:515-526.   DOI   ScienceOn
18 Klass, D.L. 1974. Perpetual methane economy- is it possible? Chemische Technik. 3:161-168.
19 Liu, G., R. Zhang, R. H.M. El-Mashad, and R. Dong. 2009. Effect of feed to inoculum ratios on biogas yields of food and green wastes. Bioresour. Technol. 100:5103-5108.   DOI
20 Lee, D.H. S.K. Behera, J.W. Kim, and H.S. Park. 2009. Methane production potential of leachate generated from Korean food waste recycling facilities: A lab-scale study. Waste Manage. 29:876-882.   DOI
21 Oslaj, M., B. Mursec, and P. Vindis. 2010. Biogas production from maize hybrids. Biomass Bioenergy. 34:1538-1545.   DOI
22 Owen, W.F., D.C. Stuckey, and J.B.Healy Jr. 1979. Bioassay for monitoring biochemical methane potential and anaerobic toxicity. Water Res. 13:485-492.   DOI   ScienceOn
23 Raposo, F., C.J. Banks, I. Siegert, S. Heaven, and R. Borja. 2006. Influence of inoculum to substrate ratio on the biochemical methane potential of maize in batch tests. Process Biochem. 41:1444-1450.   DOI
24 Rincon, B., C.J. Banks, and S. Heaven. 2010. Biochemical methane potential of winter wheat (Triticum aestivum L.): Influence of growth stage and storage practice. Bioresour. Technol. 101:8179-8184.   DOI
25 Sialve, B., N. Bernet, and O. Bernard. 2009. Anaerobic digestion of microalgae as a necessary step to make microalgal biodiesel sustainable. Biotechnol. Adv. 27:409-416.   DOI
26 Speece, R. 1996. Anaerobic biotechnology for industrial wastewaters. Nashville: Archae press.
27 Van Ginkel, S.W., S.E. Oh, and B.E. Logan. 2005. Biohydrogen gas production from food processing and domestic wastewaters. Int. J. Hydro. Energy. 30:1535-1542.   DOI
28 Weiland, P. 2010. Biogas production: Current state and perspectives. Appl. Microbiol. Biotechnol. 85:849-860.   DOI
29 Vergara-Fernandez, A., G. Vargas, N. Alarcon, and A. Velasco. 2008. Evaluation of marine algae as a source of biogas in a two-stage anaerobic reactor system. Biomass Bioenergy. 32:338-344.   DOI
30 Vindis, P., B. Mursec, M. Janzekovic, and F. Cus. 2007. Processing of soyabean meal into concentrates and testing for genetically modified organism (GMO). J. Achieve Mat. Manu. Eng. 20:507-510.
31 Yokoyama, S., K. Jonouchi, and K. Imou. 2007. Energy production from marine biobass: Fuel cell power generation driven by methane produced from seaweed. W. Aca. Sci. Eng. Technol. 28:320-322.
32 Zhang, R., H.M. El-Mashad, K. Hartman, F. Wang, G. Liu, C. Choate, and P. Gamble. 2007. Characterization of food waste as feedstock for anaerobic digestion. Bioresour. Technol. 98:929-935.   DOI
33 Zwietering, M.H., I. Jongenburger, F.M. Rombouts, and K. VAN 'T Riet. 1990. Modeling of the Bacterial Growth Curve. Appl. Environ. Microbiol. 56:1875-1881.