Application of a modified Anaerobic Digestion Model 1 version for fermentative hydrogen production from sweet sorghum extract by Ruminococcus albus

International Journal of Hydrogen Energy

Volumn 35, Issue 8, 2010, Pages 3423-3432

  Ntaikou, I ^a,b   Gavala, H N ^a,c   Lyberatos, G ^a,b  

^a UNIVERSITY OF PATRAS   (Greece)

^b INSTITUTE OF CHEMICAL ENGINEERING SCIENCES   (Greece)

^c AALBORG UNIVERSITY   (Denmark)

Author keywords

ADM1; Biohydrogen; Biomass; Kinetic model; Ruminococcus albus; Sweet sorghum

Indexed keywords

ADM1; ADM1 MODELS; ANAEROBIC DIGESTION MODEL 1; BATCH CULTURE; BATCH EXPERIMENTS; BIO-HYDROGEN; BIPHASIC GROWTH; CARBON SOURCE; CONTINUOUS CULTURE; EFFECT OF PH; EXPERIMENTAL DATA; FERMENTATIVE HYDROGEN PRODUCTION; HYDROGEN PARTIAL PRESSURES; HYDROGEN PRODUCTION PROCESS; HYDROGEN YIELDS; INITIAL CONCENTRATION; KINETIC MODELS; MODEL PREDICTION; SOLE CARBON SOURCE; SWEET SORGHUM; SYNTHETIC SUBSTRATES;

ANAEROBIC DIGESTION; BATCH CELL CULTURE; EXPERIMENTS; GAS PRODUCERS; GLUCOSE; GROWTH KINETICS; HYDROGEN PRODUCTION; KINETIC THEORY; PH EFFECTS; PRESSURE EFFECTS; SUGAR (SUCROSE);

SUBSTRATES;

EID: 77950296752     PISSN: 03603199     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijhydene.2010.01.118     Document Type: Article

References (81)

1. Dunn S. Hydrogen futures: toward a sustainable energy system. Int J Hydrogen Energy 27 3 (2002) 235-264
2. Momirlan M., and Veziroglu T.N. The properties of hydrogen as fuel tomorrow in sustainable energy system for a cleaner planet. Int J Hydrogen Energy 30 (2005) 795-802
3. Marban G., and Valdes-Solis T. Towards the hydrogen economy?. Int J Hydrogen Energy 32 (2007) 1625-1637
4. 2 now or later?. Energy Policy 35 (2007) 1315-1329
5. Muradov N.Z., and Veziroglu T.N. Green path from fossil-based to hydrogen economy: An overview of carbon-neutral technologies. Int J Hydrogen Energy 33 23 (2008) 6804-6839
6. Moriarty P., and Honnery D. Hydrogen's role in an uncertain energy future. Int J Hydrogen Energy 34 1 (2009) 31-39
7. Tuna E., Kargi F., and Argun H. Hydrogen gas production by electrohydrolysis of volatile fatty acid (VFA) containing dark fermentation effluent. Int J Hydrogen Energy 34 1 (2009) 262-269
8. Gnansounou E., Dauriat A., Villegas J., and Panichelli L. Life cycle assessment of biofuels: Energy and greenhouse gas balances. Bioresource Technol 100 21 (2009) 4919-4930
9. Dimopoulos P., Bach C., Soltic P., and Boulouchos K. Hydrogen-natural gas blends fuelling passenger car engines: combustion, emissions and well-to-wheels assessment. Int J Hydrogen Energ 33 23 (2008) 7224-7236
10. 2 absorbent: the microstructure of char and absorbent. Int J Hydrogen Energy 33 20 (2008) 5422-5429
11. Digman B., Joo H.S., and Kim D.-S. Recent progress in gasification/pyrolysis technologies for biomass conversion to energy. Environ Prog Sustain Energy 28 1 (2009) 47-51
12. Kirubakaran V., Sivaramakrishnan V., Nalini R., Sekar T., Premalatha M., and Subramanian P. A review on gasification of biomass. Renew Sust Energ Rev 13 1 (2009) 179-186
13. Redwood M.D., and Macaskie L.E. A two-stage, two-organism process for biohydrogen from glucose. Int J Hydrogen Energy 31 11 (2006) 1514-1521
14. Kim E.-J., Kim M.-S., and Lee J.K. Hydrogen evolution under photoheterotrophic and dark fermentative conditions by recombinant Rhodobacter sphaeroides containing the genes for fermentative pyruvate metabolism of Rhodospirillum rubrum. Int J Hydrogen Energy 33 19 (2008) 5131-5136
15. Uyar B., Eroglu I., Yücel M., and Gündüz U. Photofermentative hydrogen production from volatile fatty acids present in dark fermentation effluents. Int J Hydrogen Energy 34 10 (2009) 4517-4523
16. Nandi R., and Sengupta R. Microbial production of hydrogen: an overview. Crit Rev Microbiol 24 1 (1998) 61-84
17. Mortlock M.Y., and Hammer G.L. Genotype and water limitation effects on transpiration efficiency in sorghum. J Crop Prod 2 2 (1999) 265-286
18. Unlu M., and Steduto P. Comparison of photosynthetic water use efficiency of sweet sorghum at canopy and leaf scales. Turk J Agric For 24 4 (2000) 519-525
19. Billa E., Koullas D.P., Monties B., and Koukios E.G. Structure and composition of sweet sorghum stalk components. Ind Crop Prod 6 3-4 (1997) 297-302
20. Worley J.W., Vaughan D.H., and Cundiff J.S. Energy analysis of ethanol production from sweet sorghum. Bioresource Technol 40 3 (1992) 263-273
21. Mamma D., Christakopoulos P., Koullas D., Kekos D., Macris B.J., and Koukios E. An alternative approach to the bioconversion of sweet sorghum carbohydrates to ethanol. Biomass Bioenerg 8 2 (1995) 99-103
22. Cunningham R.L., Carlson K.D., and Bagby M.O. Extracted sweet sorghum substrates as a source of fermentable sugars. App Biochem Biotech 17 1-3 (1988) 117-124
23. Ballesteros M., Oliva J.M., Negro M.J., Manzanares P., and Ballesteros I. Ethanol from lignocellulosic materials by a simultaneous saccharification and fermentation process (SFS) with Kluyveromyces marxianus CECT 10875. Process Biochem 39 (2004) 1843-1848
24. Christakopoulos P., Li L.W., Kekos D., and Macris B.J. Direct conversion of sorghum carbohydrates to ethanol by a mixed microbial culture. Bioresource Technol 45 (1993) 89-92
25. Gnansounou E., Dauriat A., and Wyman C.E. Refining sweet sorghum to ethanol and sugar: economic trade-offs in the context of North China. Bioresource Technol 96 9 (2005) 985-1002
26. Horn C.H., du Preez J.C., and Kilian S.G. Fermentation of grain sorghum starch by co-cultivation of Schwanniomyces occidentalis and Saccharomyces cerevisiae. Bioresource Technol 42 1 (1992) 27-31
27. Claassen PAM, de Vrije T, Budde MAW. Biological hydrogen production from sweet sorghum by thermophilic bacteria. 2nd World Conference on Biomass for Energy, Industry and Climate Protection. Rome, Italy; 10-14 May 2004.
28. Antonopoulou A., Ntaikou I., Gavala H.N., Skiadas I.V., Angelopoulos K., and Lyberatos G. Biohydrogen production from sweet sorghum biomass using mixed acidogenic cultures and pure cultures of Ruminococcus albus. Global NEST J 2 (2007) 144-151
29. Antonopoulou A., Gavala H.N., Skiadas I.V., Angelopoulos K., and Lyberatos G. Biofuels generation from sweet sorghum: fermentative hydrogen production and anaerobic digestion of the remaining biomass. Bioresource Technol 99 (2008) 110-119
30. Ntaikou I., Gavala H.N., Kornaros A., and Lyberatos G. Hydrogen production from sugars and sweet sorghum biomass using Ruminococcus albus. Int J Hydrogen Energy 33 4 (2008) 1153-1163
31. Ivanova G., Rákhely G., and Kovács K.L. Thermophilic biohydrogen production from energy plants by Caldicellulosiruptor saccharolyticus and comparison with related studies. Int J Hydrogen Energy 34 9 (2009) 3659-3670
32. Shi X.-X., Song H.-C., Wang C.-R., Tang R.-S., Huang Z.-X., Gao T.-R., et al. Enhanced bio-hydrogen production from sweet sorghum stalk with alkalization pretreatment by mixed anaerobic cultures. Int J Energ Res (2009) 10.1002/er.1570
33. Wang J., and Wan W. Factors influencing fermentative hydrogen production: a review. Int J Hydrogen Energy 34 2 (2009) 799-811
34. Kumar A., Jain S.R., Kalia V.C., and Joshi A.P. Effect of some physiological factors on nitrogenase activity and nitrogenase mediated hydrogen evolution by mixed microbial culture. Biochem Mol Biol Int 45 2 (1998) 245-253
35. Zhang T., Liu H., and Fang H.H.P. Biohydrogen production from starch in wastewater under thermophilic condition. J Environ Manage 69 2 (2003) 149-156
36. Hussy I., Hawkes F.R., Dinsdale R., and Hawkes D.L. Continuous fermentative hydrogen production from sucrose and sugarbeet. Int J Hydrogen Energy 30 5 (2005) 471-483
37. Koutrouli E.C., Gavala H.N., Skiadas I.V., and Lyberatos G. Mesophilic biohydrogen production from olive pulp. Process Saf Environ 84 4B (2006) 285-289
38. Wang C.-H., Lu W.-B., and Chang J.-S. Feasibility study on fermentative conversion of raw and hydrolyzed starch to hydrogen using anaerobic mixed microflora. Int J Hydrogen Energy 31 16 (2007) 3849-3859
39. Ntaikou I., Kourmentza C., Koutrouli E.C., Stamatelatou K., Zampraka A., Kornaros M., et al. Exploitation of olive oil mill wastewater for combined biohydrogen and biopolymers production. Bioresour Technol 100 15 (2009) 3724-3730
40. Gavala H.N., Skiadas I.V., and Ahring B.K. Biological hydrogen production in suspended and attached growth anaerobic reactor systems. Int J Hydrogen Energy 31 9 (2009) 1164-1175
41. Koutrouli E.C., Kalfas H., Gavala H.N., Skiadas I.V., Stamatelatou K., and Lyberatos G. Hydrogen and methane production through two-stage mesophilic anaerobic digestion of olive pulp. Bioresour Technol 100 15 (2009) 3718-3723
42. Taguchi F., Mizukami N., Hasegawa K., Saito-Taki T., and Morimoto M. Effect of amylase accumulation on hydrogen production by Clostridium beijerinckii, strain AM21B. J Ferment Bioeng 77 5 (1994) 565-567
43. Chin H.-L., Chen Z.-S., and Chou C.P. Fedbatch operation using Clostridium acetobutylicum suspension culture as biocatalyst for enhancing hydrogen production. Biotechnol Progr 19 2 (2003) 383-388
44. Collet C., Adler N., Schwitzguebel J.-P., and Peringer P. Hydrogen production by Clostridium thermolacticum during continuous fermentation of lactose. Int J Hydrogen Energy 29 14 (2004) 1479-1485
45. Chen W.-M., Tseng Z.-J., Lee K.S., and Chang J.-S. Fermentative hydrogen production with Clostridium butyricum CGS5 isolated from anaerobic sewage sludge. Int J Hydrogen Energy 30 10 (2005) 1063-1070
46. Levin D.B., Islam R., Cicek N., and Sparling R. Hydrogen production by Clostridium thermocellum 27405 from cellulosic biomass substrates. Int J Hydrogen Energy 31 11 (2006) 1496-1503
47. Zhang H., Bruns M.A., and Logan B.E. Biological hydrogen production by Clostridium acetobutylicum in an unsaturated flow reactor. Water Res 40 4 (2006) 728-734
48. Liu Y., Yu P., Song X., and Qu Y. Hydrogen production from cellulose by co-culture of Clostridium thermocellum JN4 and Thermoanaerobacterium thermosaccharolyticum GD17. Int J Hydrogen Energy 33 12 (2008) 2927-2933
49. Wang A., Ren N., Shi Y., and Lee D.-J. Bioaugmented hydrogen production from microcrystalline cellulose using co-culture- Clostridium acetobutylicumX9 and Ethanoigenens harbinenseB49. Int J Hydrogen Energy 33 2 (2008) 912-917
50. Ntaikou I., Koutros E., and Kornaros M. Valorization of wastepaper using the/hydrogen producing bacterium Ruminococcus albus. Bioresour Technol 100 23 (2009) 5928-5933
51. Ueno Y., Kawai T., Sato S., Otsuka S., and Morimoto M. Biological production of hydrogen from cellulose by natural anaerobic microflora. J Ferment Bioeng 79 4 (1995) 395-397
52. Mi-Sun K., Moon K.-W., Lee I.-G., Lee T.-J., and Sung C.-K. Hydrogen gas production by fermentation from various sugars using Clostridium butyricum NCIB 9576. Kor L Appl Microbiol Biot 27 1 (1999) 62-69
53. Lin C.Y., and Chou C.H. Anaerobic hydrogen production from sucrose using an acid-enriched sewage sludge microflora. Eng Life Sci 4 1 (2004) 66-70
54. Zhang Y., Liu G., and Shen J. Hydrogen production in batch culture of mixed bacteria with sucrose under different iron concentrations. Int J Hydrogen Energy 30 8 (2005) 855-860
55. Danko A.S., Abreu A.A., and Alves M.M. Effect of arabinose concentration on dark fermentation hydrogen production using different mixed cultures. Int J Hydrogen Energy 33 17 (2008) 4527-4532
56. Magnusson L., Cicek N., Sparling R., and Levin D. Continuous hydrogen production during fermentation of α-cellulose by the thermophillic bacterium Clostridium thermocellum. Biotechnol Bioeng 102 3 (2009) 759-766
57. Lin C.-Y., Wu C.-C., and Hung C.-H. Temperature effects on fermentative hydrogen production from xylose using mixed anaerobic cultures. Int J Hydrogen Energy 33 1 (2008) 43-50
58. Kadar Z., De Vrije T., Van Noorden G.E., Budde M.A.W., Szengyel Z., Reczey K., et al. Yields from glucose, xylose, and paper sludge hydrolysate during hydrogen production by the extreme thermophile Caldicellulosiruptor saccharolyticus. Appl Biochem Biotech 113 (2004) 497-508
59. Kim Y., Jo J.H., Lee D.S., and Park J.M. Fermentative hydrogen production from food waste. Stud Sur Sci Cat 159 (2006) 149-152
60. Li C., and Fang H.H.P. Fermentative hydrogen production from wastewater and solid wastes by mixed cultures. Crit Rev Environ Sci Tech 37 1 (2007) 1-39
61. Davila-Vazquez G., Alatriste-Mondragon F., de Leon-Rodriguez A., and Razo-Flores E. Fermentative hydrogen production in batch experiments using lactose, cheese whey and glucose: Influence of initial substrate concentration and pH. Int J Hydrogen Energy 33 19 (2008) 4989-4997
62. Saratale G.D., Chen S.-D., Lo Y.-C., and Chang J.-S. Outlook of biohydrogen production from lignocellulosic feedstock using dark fermentation - a review. J Sci Indus Res 67 11 (2008) 962-979
63. Wang J., and Wan W. Kinetic models for fermentative hydrogen production: a review. Int J Hydrogen Energy 34 8 (2009) 3313-3323
64. Batstone D.J., Keller J., Angelidaki I., Kalyuzhnyi S.V., Pavlostathis S.G., Rozzi A., et al. Anaerobic digestion Model No 1 (2002), IWA Publishing,, UK
65. Lin P.Y., Whang L.M., Wu Y.R., Ren W.J., Hsiao C.J., Li S.L., et al. Biological hydrogen production of the genus Clostridium: metabolic study and mathematical model simulation. Int J Hydrogen Energy 32 12 (2007) 1728-1735
66. Ntaikou I., Gavala H.N., and Lyberatos G. Modeling of fermentative hydrogen production from the bacterium Ruminococcus albus: definition of metabolism and kinetics during growth on glucose. Int J Hydrogen Energy 34 9 (2009) 3697-3709
67. Peiris B.R.H., Rathnasiri P.G., Johansen J.E., Kuhn A., and Bakke R. ADM1 simulations of hydrogen production. Water Sci Technol 53 8 (2006) 129-137
68. Penumathsa B.K.V., Premier G.C., Kyazze G., Dinsdale R., Guwy A.J., Esteves S., et al. ADM1 can be applied to continuous bio-hydrogen production using a variable stoichiometry approach. Water Res 42 16 (2008) 4379-4385
69. Bryant M.P., Small N., Bouma C., and Robinson I.M. Characteristics of ruminal anaerobic cellulolytic cocci and Cillobacterium cellulosolvens n. sp. J Bacteriol 76 (1958) 529-537
70. Skerman V.B.D., McGowan V., and Sneath P.H.A. Approved list of bacterial names. Int J Syst Bacteriol 30 (1980) 225-420
71. Eberlein K., and Schutt M. Automatic methods for the determination of total dissolved and particulate carbohydrates in the marine environment. Anal Bioanal Chem 323 (1986) 47-49
72. Josefsson B. Rapid spectrophotometric determination of total carbohydrates. In: Grasshoff K., Ehrhardt M., and Kremling K. (Eds). Methods of seawater analysis (1983), Verlag Chemie GmbH 340-342
73. Bradford M.M. A rapid and sensitive method for the quantification of microgram quantities of protein utilizing the principle of protein dye binding. Anal Biochem 72 (1976) 248-254
74. Reichert P. AQUASIM 2.0 Computer program for the Identification and Simulation of Aquatic Systems. EAWAG, Dubendorf, Swicherland, 1998.
75. Pavlostathis S., Miller T., and Wolin M.J. Fermentation of insoluble cellulose by continuous cultures of Ruminococcus albus. Appl Environ Microb 54 11 (1988) 2655-2659
76. Rittman B., and McCarty P.L. Environmental biotechnology: principles and applications (2000), McGraw-Hill Publications, Boston
77. Buchholz K., and Seibel J. Industrial carbohydrate biotransformations. Carboh Res 343 12 (2008) 1966-1979
78. Hungate R.E. Polysaccharide storage and growth efficiency in Ruminococcus albus. J Bacteriol 86 4 (1963) 848-854
79. Thurston B., Dawson K.A., and Strobel H.J. Cellobiose versus glucose utilization by the ruminal bacterium Ruminococcus albus. Appl Environ Microb 59 8 (1993) 2631-2637
80. Martin S.A., and Russell J.B. Transport and phosphorylation of disaccharides by the ruminal bacterium Streptococcus bovis. Appl Environ Microb 53 10 (1987) 2388-2393
81. Thurston B., Dawson K.A., and Strobel H.J. Pentoze utilization by the ruminal bacterium Ruminococcus albus. Appl Environ Microb 60 4 (1994) 1087-1092