Dark fermentation effectiveness as a key step for waste biomass refineries: Influence of organic matter macromolecular composition and bioavailability

International Journal of Energy Research

Volumn 39, Issue 11, 2015, Pages 1519-1527

  Manzini, Ester ^a   Scaglia, Barbara ^a   Schievano, Andrea ^a,b   Adani, Fabrizio ^a,b  

^a UNIVERSITY OF MILAN   (Italy)

^b PARCO TECNOLOGICO PADANO   (Italy)

Author keywords

Bio hydrogen; Biomass; Biorefinery; Carboxylates; Dark fermentation; Waste

Indexed keywords

BIOGEOCHEMISTRY; BIOMASS; CARBOXYLATION; CHEMICAL ATTACK; HYDROLYSIS; PLASTICS INDUSTRY; REFINING; SUBSTRATES; SUGARS; WASTES;

BIO-HYDROGEN; BIOREFINERIES; CARBOXYLATES; CHEMICAL COMPOSITIONS; DARK FERMENTATION; MACROMOLECULAR COMPOSITION; PARTIAL LEAST SQUARE REGRESSION; STATISTICAL MODELING;

FERMENTATION;

EID: 84938740525     PISSN: 0363907X     EISSN: 1099114X     Source Type: Journal    
DOI: 10.1002/er.3347     Document Type: Article

References (43)

1. Rabaey K, Rozendal RA. Microbial electrosynthesis-revisiting the electrical route for microbial production. Nature Reviews Microbiology 2010; 8:706-716.
2. Mohan SV, Pandey A. Biohydrogen production: an introduction. In Biohydrogen. Elsevier: Burlington, 2013; 1-24.
3. Redwood MD, Orozco RL, Majewski AJ, Macaskie LE. Electro-extractive fermentation for efficient biohydrogen production. Bioresource Technology 2012; 107:166-174.
4. Dahlqvist E (Ed.). Biomass as Energy Source: Resources, Systems and Applications. CRC Press, Taylor & Francis: London, UK, 2013.
5. Percival Zhang YH, Xu JH, Zhong JJ. A new high-energy density hydrogen carrier-carbohydrate-might be better than methanol. International Journal of Energy Research 2013; 37(7):769-779.
6. Agler MT, Wrenn BA, Zinder SH, Angenent LT. Waste to bioproduct conversion with undefined mixed cultures: the carboxylate platform. Trends in Biotechnology 2011; 29(2):70-78. doi:10.1016/j.tibtech.2010.11.006.
7. Adani F, Papa G, Schievano A, Cardinale G, D'Imporzano G, Tambone F. Nanoscale structure of the cell wall protecting cellulose from enzyme attack. Environmental Science & Technology 2011; 45:1107-1113.
8. Redwood MD, Orozco RL, Majewski AJ, Macaskie LE. An integrated biohydrogen refinery: synergy of photofermentation, extractive fermentation and hydrothermal hydrolysis of food wastes. Bioresource Technology 2012; 119:384-392.
9. Lee WE, May Chua AS, Yeoh HK, Ngoh GC. A review of the production and applications of waste-derived volatile fatty acids. Chemical Engineering Journal 2014; 235:83-99.
10. Singhania RR, Patel AK, Christophe G, Fontanille P, Larroche C. Biological upgrading of volatile fatty acids, key intermediates for the valorization of biowaste through dark anaerobic fermentation. Bioresource Technology 2013; 145:166-174.
11. Hallenbeck PC. Fundamentals of biohydrogen. In Biohydrogen. Elsevier: Burlington, 2013; 25-43.
12. Liu K, Atiyeh HK, Stevenson BS, Tanner RS, Wilkins MR, Huhnke RL. Mixed culture syngas fermentation and conversion of carboxylic acids into alcohols. Bioresource Technology 2014; 152:337-346.
13. Schievano A, Tenca A, Scaglia B, Merlino G, Rizzi A, Daffonchio D, Oberti R, Adani F. Two-stage vs single-stage thermophilic anaerobic digestion: comparison of energy production and biodegradation efficiencies. Environmental Science & Technology 2012; 46:8502-8510. doi: 10.1021/es301376n
14. Monlau F, Sambusiti C, Barakat A, Quéméneur M, Trably E, Steyer JP, Carrère H. Do furanic and phenolic compounds of lignocellulosic and algae biomass hydrolyzate inhibit anaerobic mixed cultures? A comprehensive review. Biotechnology Advances 2014; 32:934-951.
15. Yokoi H, Saitsu A, Uchida H, Hirose J, Hayashi S, Takasaky Y. Microbial hydrogen production from sweet potato starch residue. Journal of Bioscience and Bioengineering 2001; 91:58-63.
16. Kapdan IK, Kargi F. Bio-hydrogen production from waste materials. Enzyme and Microbial Technology 2006; 38:569-582.
17. Lay J, Fan K, Chang J, Ku K. Influence of chemical nature of organic wastes on their conversion to hydrogen by heat-shock digested sludge. International Journal of Hydrogen Energy 2003; 28:1361-1367.
18. Silvestre G, Illa J, Fernández B, Bonmatí A. Thermophilic anaerobic co-digestion of sewage sludge with grease waste: effect of long chain fatty acids in the methane yield and its dewatering properties. Applied Energy 2014; 117:87-94.
19. Schievano A, Scaglia B, D'Imporzano G, Malagutti L, Gozzi A, Adani F. Prediction of biogas potentials using quick laboratory analyses: upgrading previous models for application to heterogeneous organic matrices. Bioresource Technology 2009; 100:5777-82.
20. Sluiter A. Determination of Total Solids in Biomass Natl Renew Energy Lab. : Golden, CO, USA, 2005.
21. Lahav O, Morgan B, Loewenthal RE. Rapid, simple and accurate method for measurement of VFA and carbonate alkalinity in anaerobic reactors. Environmental Science & Technology 2002; 36:2736-3274.
22. Bremner JM. Nitrogen-total. Methods of soil analysis, part 3-chemical methods. 1996; 1085-1121.
23. Van Soest PJ, Robertson JB, Lewis BA. Methods for Dietary Fiber, Neutral Detergent Fiber, and Nonstarch Polysaccharides in Relation to Animal Nutrition. Cornell University, Department of Animal Science and Division of Nutritional Science: Ithaca, NY, 1991.
24. AOAC. Official Methods of Analysis (13th). Association of Analytical Chemist: Washington, 1980.
25. Dubois M, Gilles KA, Hamilton JK, Rebers PA, Smith F. Colorimetric method for determination of sugar and related substances. Analytical Chemistry 1956; 28:350-356.
26. MEGAZYME Assay Procedure (Amyloglucosidase/α-Amylase method), K-TSTA 04/2009.
27. Robinson PH, Campbell Mathews M, Fadel JG. Influence of storage time and temperature on in vitro digestion of neutral detergent fibre at 48h, and comparison to 48h in sacco neutral detergent fibre digestion. Animal Feed Science and Technology 1999; 80:257-266.
28. Schievano A, Pognani M, D'Imporzano G, Adani F. Predicting anaerobic biogasification potential of ingestates and digestates of a full-scale biogas plant using chemical and biological parameters. Bioresource Technology 2008; 99:8112-8117.
29. Tenca A, Schievano A, Lonati S, Malagutti L, Oberti R, Adani F. Looking for practical tools to achieve next-future applicability of dark fermentation to produce bio-hydrogen from organic materials in Continuously Stirred Tank Reactors. Bioresource Technology 2011; 102:7910-7916.
30. Tenca A, Schievano A, Perazzolo F, Adani F, Oberti R. Biohydrogen from thermophilic co-fermentation of swine manure with fruit and vegetable waste: maximizing stable production without pH control. Bioresource Technology 2011; 102:8582-8588.
31. Sheskin DJ. Handbook of Parametric and Nonparametric Statistical Procedures (3rd). CRC press: US, 2003.
32. Andries PMJ, Heyden YV, Buydens LMC. Improved variable reduction in partial least squares modelling based on Predictive-Property-Ranked Variables and adaptation of partial least squares complexity. Analytica Chimica Acta 2011; 705:292-305.
33. Nagaraja TG, Titgemeyer EC. Ruminal acidosis in beef cattle: the current microbiological and nutritional outlook. Journal of Dairy Science 2007; 90(1):17-38.
34. Schievano A, D'Imporzano G, Malagutti L, Fragali E, Ruboni G, Adani F. Evaluating inhibition conditions in high-solids anaerobic digestion of organic fraction of municipal solid waste. Bioresource Technology 2010; 101(14):5728-5732.
35. Papa G, Scaglia B, Schievano A, Adani A. Nanoscale structure of organic matter could explain litter decomposition. Biogeochemistry 2013. doi:10.1007/s10533-013-9863-z.
36. Akutsu Y, Li Y, Harada H, Yu H. Effect of temperature and substrate concentration on biological hydrogen production from starch. International Journal of Hydrogen Energy 2009; 34:2558-2566.
37. Noike T, Mizuno O. Hydrogen fermentation from municipal wastes. Water Science and Technology 2000; 42:155-162.
38. Yu H, Zhu Z, Hu W, Zhang H. Hydrogen production from rice winery wastewater in an upflow anaerobic reactor by using mixed anaerobic cultures. International Journal of Hydrogen Energy 2002; 27:1359-1365.
39. Li Q, Guo C, Liu CZ. Dynamic microwave-assisted alkali pretreatment of cornstalk to enhance hydrogen production via co-culture fermentation of Clostridium thermocellum and Clostridium thermosaccharolyticum. Biomass and Bioenergy 2014; 64:220-229.
40. Ozmihci S, Kargi F, Cakir A. Thermophilic dark fermentation of acid hydrolyzed waste ground wheat for hydrogen gas production. International Journal of Hydrogen Energy 2011; 36:2111-2117.
41. Davila-Vazquez G, Alatriste-Mondragón F, de León-Rodríguez A, Razo-Flores E. Fermentative hydrogen production in batch experiments using lactose, cheese whey and glucose: influence of initial substrate concentration and pH. International Journal of Hydrogen Energy 2008; 33:4989-4997.
42. Gunaseelan VN. Regression models of ultimate methane yields of fruits and vegetable solid wastes, sorghum and napiergrass on chemical composition. Bioresource Technology 2007; 98:1270-1277.
43. Rabaey K, Ragauskas AJ. Editorial overview: energy biotechnology. Current Opinion in Biotechnology 2014; 27:5-6.