Enhancement of biogas and methanization of citrus waste via biodegradation pretreatment and subsequent optimized fermentation

Fuel

Volumn 181, Issue , 2016, Pages 843-851

  Su, Haifeng ^a   Tan, Furong ^a   Xu, Yuanjian ^b  

^a AGRO ENVIRONMENTAL PROTECTION INSTITUTE   (China)

^b University of Chinese Academy of Sciences   (China)

Author keywords

Anaerobic fermentation; Biodegradation pretreatment; Biogas; Citrus waste

Indexed keywords

ASPERGILLUS; BIOGAS; FERMENTATION; METHANE; PH EFFECTS; POLLUTION; REDOX REACTIONS; RIVER POLLUTION; SOLID WASTES; SURFACE WATERS; WATER POLLUTION;

ANAEROBIC FERMENTATION; CITRUS WASTES; ENVIRONMENTAL POLLUTION PROBLEM; MULTI-STAGE OPTIMIZATION; OXIDATION REDUCTION POTENTIAL; PHANEROCHAETE CHRYSOSPORIUM; PRE-TREATMENT; STEP BY STEP PROCEDURE;

BIODEGRADATION;

EID: 84971254754     PISSN: 00162361     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.fuel.2016.05.055     Document Type: Article

References (36)

1. [1] Elbersen, B., Fritsche, U., Petersen, J.E., Lesschen, J.P., Böttcher, H., Overmars, K., Assessing the effect of stricter sustainability criteria on EU biomass crop potential. Biofuels, Bioprod Biorefin 7 (2013), 173–192.
2. [2] Schnepf, R., Agriculture-based biofuels: overview and emerging issues. 2013, BiblioGov.
3. [3] Wang, X., Chen, Q., Lü, X., Pectin extracted from apple pomace and citrus peel by subcritical water. Food Hydrocolloids 38 (2014), 129–137.
4. [4] Hou, X., Chen, X., Cheng, Y., Xu, H., Chen, L., Yang, Y., Dyeing and UV-protection properties of water extracts from orange peel. J Clean Prod 52 (2013), 410–419.
5. [5] Wang, L., Wang, J., Fang, L., Zheng, Z., Zhi, D., Wang, S., et al. Anticancer activities of citrus peel polymethoxyflavones related to angiogenesis and others. BioMed Res, 2014.
6. [6] Boluda-Aguilar, M., López-Gómez, A., Production of bioethanol by fermentation of lemon (Citrus limon L.) peel wastes pretreated with steam explosion. Ind Crops Prod 41 (2013), 188–197.
7. [7] Widmer, W., Zhou, W., Grohmann, K., Pretreatment effects on orange processing waste for making ethanol by simultaneous saccharification and fermentation. Bioresour Technol 101 (2010), 5242–5249.
8. [8] Oberoi, H.S., Vadlani, P.V., Madl, R.L., Saida, L., Abeykoon, J.P., Ethanol production from orange peels: two-stage hydrolysis and fermentation studies using optimized parameters through experimental design. J Agric Food Chem 58 (2010), 3422–3429.
9. [9] Boluda-Aguilar, M., García-Vidal, L., del Pilar González-Castañeda, F., López-Gómez, A., Mandarin peel wastes pretreatment with steam explosion for bioethanol production. Bioresour Technol 101:10 (2010), 3506–3513.
10. [10] Danial, A.W., Abdel-Basset, R., Orange peel inhibited hup and enhanced hydrogen evolution in some purple non-sulfur bacteria. Int J Hydrogen Energy 40 (2015), 941–947.
11. [11] Asgher, M., Bhatti, H.N., Mechanistic and kinetic evaluation of biosorption of reactive azo dyes by free, immobilized and chemically treated Citrus sinensis waste biomass. Ecol Eng 36 (2010), 1660–1665.
12. [12] Lohrasbi, M., Pourbafrani, M., Niklasson, C., Taherzadeh, M.J., Process design and economic analysis of a citrus waste biorefinery with biofuels and limonene as products. Bioresour Technol 101 (2010), 7382–7388.
13. [13] Pourbafrani, M., Forgács, G., Horváth, I.S., Niklasson, C., Taherzadeh, M.J., Production of biofuels, limonene and pectin from citrus wastes. Bioresour Technol 101 (2010), 4246–4250.
14. [14] Forgács, G., Pourbafrani, M., Niklasson, C., Taherzadeh, M.J., Hováth, I.S., Methane production from citrus wastes: process development and cost estimation. J Chem Technol Biotechnol 87 (2012), 250–255.
15. [15] Wan, C., Li, Y., Solid-state biological pretreatment of lignocellulosic biomass. Gu, T., (eds.) Green biomass pretreatment for biofuels production, 2013, Springer, Netherlands, 67–86.
16. [16] Tinggi, U., Reilly, C., Patterson, C., Determination of manganese and chromium in foods by atomic absorption spectrometry after wet digestion. Food Chem 60 (1997), 123–128.
17. [17] Voegborlo, R., Adimado, A., A simple classical wet digestion technique for the determination of total mercury in fish tissue by cold-vapour atomic absorption spectrometry in a low technology environment. Food Chem 123 (2010), 936–940.
18. [18] Batjes, N.H., Total carbon and nitrogen in the soils of the world. Eur J Soil sci 47 (1996), 151–163.
19. [19] Nelson DW, Sommers LE. Total carbon, organic carbon, and organic matter, Methods of soil analysis Part, vol. 3; 1996. p. 961–1010.
20. [20] Hoban, D., Berg, L., Effect of iron on conversion of acetic acid to methane during methanogenic fermentations. J Appl Bacteriol 47 (1979), 153–159.
21. [21] Buswell, A., Mueller, H., Mechanism of methane fermentation. Ind Eng Chem 44 (1952), 550–552.
22. [22] Wang, Z., Delaune, R., Patrick, W., Masscheleyn, P., Soil redox and pH effects on methane production in a flooded rice soil. Soil Sci Soc Am J 57 (1993), 382–385.
23. [23] Ye, R., Jin, Q., Bohannan, B., Keller, J.K., McAllister, S.A., Bridgham, S.D., PH controls over anaerobic carbon mineralization, the efficiency of methane production, and methanogenic pathways in peatlands across an ombrotrophic–minerotrophic gradient. Soil Biology Biochem 54 (2012), 36–47.
24. [24] Bryant, M., Microbial methane production—theoretical aspects. J Ani Sci 48 (1979), 193–201.
25. [25] Russell, J., Another explanation for the toxicity of fermentation acids at low pH: anion accumulation versus uncoupling. J Appl Bacteriol 73 (1992), 363–370.
26. [26] Li, Yanbin, Zhang, L., Room temperature anaerobic digestion technology processing research of citrus wastes. Energy Eng 5 (2007), 35–38 [in Chinese].
27. [27] Yu, Y., Zeng, Y., Zuo, J., Ma, F., Yang, X., Zhang, X., et al. Improving the conversion of biomass in catalytic fast pyrolysis via white-rot fungal pretreatment. Bioresour Technol 134 (2013), 198–203.
28. [28] Zhu, R., Lu, L., Guo, J., Lu, H., Abudureheman, N., Yu, T., et al. Postharvest control of green mold decay of citrus fruit using combined treatment with sodium bicarbonate and Rhodosporidium paludigenum. Food Bioprod Technol 6 (2013), 2925–2930.
29. [29] Shi, J., Wang, Z., Stiverson, J.A., Yu, Z., Li, Y., Reactor performance and microbial community dynamics during solid-state anaerobic digestion of corn stover at mesophilic and thermophilic conditions. Bioresour Technol 136 (2013), 574–581.
30. [30] Ziganshin, A.M., Liebetrau, J., Pröter, J., Kleinsteuber, S., Microbial community structure and dynamics during anaerobic digestion of various agricultural waste materials. Appl Microbiol Biotechnol 97 (2013), 5161–5174.
31. [31] Nghiem, L.D., Manassa, P., Dawson, M., Fitzgerald, S.K., Oxidation reduction potential as a parameter to regulate micro-oxygen injection into anaerobic digester for reducing hydrogen sulphide concentration in biogas. Bioresour Technol 173 (2014), 443–447.
32. [32] Yu, B., Xu, J., Yuan, H., Lou, Z., Lin, J., Zhu, N., Enhancement of anaerobic digestion of waste activated sludge by electrochemical pretreatment. Fuel 130 (2014), 279–285.
33. [33] Zhou, A., Guo, Z., Yang, C., Kong, F., Liu, W., Wang, A., Volatile fatty acids productivity by anaerobic co-digesting waste activated sludge and corn straw: effect of feedstock proportion. J Biotechnol 168 (2013), 234–239.
34. [34] McMahon, K.D., Zheng, D., Stams, A.J., Mackie, R.I., Raskin, L., Microbial population dynamics during start-up and overload conditions of anaerobic digesters treating municipal solid waste and sewage sludge. Biotechnol Bioeng 87 (2004), 823–834.
35. [35] Menardo, S., Gioelli, F., Balsari, P., The methane yield of digestate: effect of organic loading rate, hydraulic retention time, and plant feeding. Bioresour Technol 102:3 (2011), 2348–2351.
36. [36] Mähnert, P., Linke, B., Kinetic study of biogas production from energy crops and animal waste slurry: effect of organic loading rate and reactor size. Environ Technol 30 (2009), 93–99.