The Effect of Magnetite Particle Size on Methane Production by Fresh and Degassed Anaerobic Sludge

E. Al-Essa; R. Bello-Mendoza; D. G. Wareham

Open Science Index

Commenced in January 2007

Frequency: Monthly

Edition: International

Publications Count: 31097

10011043

The Effect of Magnetite Particle Size on Methane Production by Fresh and Degassed Anaerobic Sludge

Authors:

E. Al-Essa, R. Bello-Mendoza, D. G. Wareham

Abstract:

Anaerobic batch experiments were conducted to investigate the effect of magnetite-supplementation (7 mM) on methane production from digested sludge undergoing two different microbial growth phases, namely fresh sludge (exponential growth phase) and degassed sludge (endogenous decay phase). Three different particle sizes were assessed: small (50 - 150 nm), medium (168 – 490 nm) and large (800 nm - 4.5 µm) particles. Results show that, in the case of the fresh sludge, magnetite significantly enhanced the methane production rate (up to 32%) and reduced the lag phase (by 15% - 41%) as compared to the control, regardless of the particle size used. However, the cumulative methane produced at the end of the incubation was comparable in all treatment and control bottles. In the case of the degassed sludge, only the medium-sized magnetite particles increased significantly the methane production rate (12% higher) as compared to the control. Small and large particles had little effect on the methane production rate but did result in an extended lag phase which led to significantly lower cumulative methane production at the end of the incubation period. These results suggest that magnetite produces a clear and positive effect on methane production only when an active and balanced microbial community is present in the anaerobic digester. It is concluded that, (i) the effect of magnetite particle size on increasing the methane production rate and reducing lag phase duration is strongly influenced by the initial metabolic state of the microbial consortium, and (ii) the particle size would positively affect the methane production if it is provided within the nanometer size range.

Keywords:

Anaerobic digestion, iron oxide (Fe3O4), methanogenesis, nanoparticle.

Digital Object Identifier (DOI):

doi.org/10.5281/zenodo.10.5281/zenodo.3669254

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO690 PDF

313

downloads

References:

[1] S. Achinas, V. Achinas, and G. J. W. Euverink, "A technological overview of biogas production from biowaste," Engineering, vol. 3, no. 3, pp. 299-307, 2017.
[2] F. Liu, A.-E. Rotaru, P. M. Shrestha, N. S. Malvankar, K. P. Nevin, and D. R. Lovley, "Promoting Direct Interspecies Electron Transfer with Activated Carbon," Energy & Environmental Science, vol. 5, no. 10, pp. 8982-8989, 2012.
[3] S. Chen et al., "Carbon cloth stimulates direct interspecies electron transfer in syntrophic co-cultures," Bioresource Technology, vol. 173, pp. 82-86, 2014.
[4] Z. Zhao, Y. Zhang, T. Woodard, K. Nevin, and D. Lovley, "Enhancing Syntrophic Metabolism in up-Flow Anaerobic Sludge Blanket Reactors with Conductive Carbon Materials," Bioresource Technology, vol. 191, pp. 140-145, 2015.
[5] Z. Yang, X. Shi, C. Wang, L. Wang, and R. Guo, "Magnetite nanoparticles facilitate methane production from ethanol via acting as electron acceptors," Scientific Reports, Article vol. 5, 2015, Art no. 16118.
[6] S. Zhou, J. Xu, G. Yang, and L. Zhuang, "Methanogenesis Affected by the Co-Occurrence of Iron (Iii) Oxides and Humic Substances," Fems Microbiology Ecology, vol. 88, no. 1, pp. 107-120, 2014.
[7] C. Cruz Viggi, S. Rossetti, S. Fazi, P. Paiano, M. Majone, and F. Aulenta, "Magnetite particles triggering a faster and more robust syntrophic pathway of methanogenic propionate degradation," Environmental Science and Technology, Article vol. 48, no. 13, pp. 7536-7543, 2014.
[8] E. Abdelsalam, M. Samer, Y. Attia, M. Abdel-Hadi, H. Hassan, and Y. Badr, "Influence of zero valent iron nanoparticles and magnetic iron oxide nanoparticles on biogas and methane production from anaerobic digestion of manure," Energy, vol. 120, pp. 842-853, 2017.
[9] S. Kato, K. Hashimoto, and K. Watanabe, "Methanogenesis facilitated by electric syntrophy via (semi) conductive iron‐oxide minerals," Environmental Microbiology, vol. 14, no. 7, pp. 1646-1654, 2012.
[10] Z. Yang, X. Xu, R. Guo, X. Fan, and X. Zhao, "Accelerated methanogenesis from effluents of hydrogen-producing stage in anaerobic digestion by mixed cultures enriched with acetate and nano-sized magnetite particles," Bioresource Technology, vol. 190, pp. 132-139, 2015.
[11] Z. Yang, R. Guo, X. Shi, C. Wang, L. Wang, and M. Dai, "Magnetite Nanoparticles Enable a Rapid Conversion of Volatile Fatty Acids to Methane," Rsc Advances, vol. 6, no. 31, pp. 25662-25668, 2016.
[12] C. Yamada, S. Kato, Y. Ueno, M. Ishii, and Y. Igarashi, "Conductive iron oxides accelerate thermophilic methanogenesis from acetate and propionate," Journal of Bioscience and Bioengineering, Article vol. 119, no. 6, pp. 678-682, 2015.
[13] I. Angelidaki et al., "Defining the biomethane potential (BMP) of solid organic wastes and energy crops: a proposed protocol for batch assays," Water Science and Technology, vol. 59, no. 5, pp. 927-934, 2009.
[14] A. Hadiyarto, B. Budiyono, S. Djohari, I. Hutama, and W. Hasyim, "The Effect of F/M Ratio to the Anaerobic Decomposition of Biogas Production from Fish Offal Waste," Waste Technology, vol. 3, no. 2, pp. 58-61, 2015.
[15] J. De Vrieze et al., "Inoculum selection influences the biochemical methane potential of agro‐industrial substrates," Microbial Biotechnology, vol. 8, no. 5, pp. 776-786, 2015.
[16] F. D. Manure, "Dairy Waste Anaerobic Digestion Handbook," 2001.
[17] Y. S. Kang, S. Risbud, J. F. Rabolt, and P. Stroeve, "Synthesis and characterization of nanometer-size Fe3O4 and γ-Fe2O3 particles," Chemistry of Materials, vol. 8, no. 9, pp. 2209-2211, 1996.
[18] X. Du, J. He, J. Zhu, L. Sun, and S. An, "Ag-deposited silica-coated Fe3O4 magnetic nanoparticles catalyzed reduction of p-nitrophenol," Applied Surface Science, vol. 258, no. 7, pp. 2717-2723, 2012.
[19] APHA, "Standard methods for the examination of water and wastewater," American Public Health Association (APHA): Washington, DC, USA, 2005.
[20] I. Angelidaki and W. Sanders, "Assessment of the anaerobic biodegradability of macropollutants," Re/Views in Environmental Science & Bio/Technology, vol. 3, no. 2, pp. 117-129, 2004.
[21] A. Nielfa, R. Cano, and M. Fdz-Polanco, "Theoretical methane production generated by the co-digestion of organic fraction municipal solid waste and biological sludge," Biotechnology Reports, vol. 5, pp. 14-21, 2015.
[22] C. Dalla Vecchiaa, A. Mattiolia, D. Bolzonellaa, E. Palmab, C. C. Viggib, and F. Aulenta, "Impact of Magnetite Nanoparticles Supplementation on the Anaerobic Digestion of Food Wastes: Batch and Continuous-Flow Investigations," Chemical Engineering Journal, vol. 49, 2016.
[23] Y. Jing, J. Wan, I. Angelidaki, S. Zhang, and G. Luo, "iTRAQ quantitative proteomic analysis reveals the pathways for methanation of propionate facilitated by magnetite," Water Research, vol. 108, pp. 212-221, 2017.
[24] E. Casals et al., "Programmed iron oxide nanoparticles disintegration in anaerobic digesters boosts biogas production," Small, vol. 10, no. 14, pp. 2801-2808, 2014.
[25] N. Maximova and O. Dahl, "Environmental Implications of Aggregation Phenomena: Current Understanding," Current Opinion in Colloid & Interface Science, vol. 11, no. 4, pp. 246-266, 2006.
[26] M. Baalousha, "Aggregation and Disaggregation of Iron Oxide Nanoparticles: Influence of Particle Concentration, Ph and Natural Organic Matter," Science of the Total Environment, vol. 407, no. 6, pp. 2093-2101, 2009.
[27] S. C. Tang and I. M. Lo, "Magnetic Nanoparticles: Essential Factors for Sustainable Environmental Applications," Water Research, vol. 47, no. 8, pp. 2613-2632, 2013.
[28] L. Regueiro et al., "Relationship between microbial activity and microbial community structure in six full-scale anaerobic digesters," Microbiological Research, vol. 167, no. 10, pp. 581-589, 2012.
[29] R. I. Amann, W. Ludwig, and K.-H. Schleifer, "Phylogenetic identification and in situ detection of individual microbial cells without cultivation," Microbiology and Molecular Biology Reviews, vol. 59, no. 1, pp. 143-169, 1995.
[30] M. T. Madigan, J. M. Martinko, P. V. Dunlap, and D. P. Clark, "Brock biology of microorganisms 12th edn," International Microbiology, vol. 11, pp. 65-73, 2008.
[31] W. D. Grant and P. E. Long, "Environmental Microbiology," in The natural environment and the biogeochemical cycles: Springer, 1985, pp. 125-237.

Vol:15 No:02 2021 Vol:15 No:01 2021
Vol:14 No:12 2020 Vol:14 No:11 2020 Vol:14 No:10 2020 Vol:14 No:09 2020 Vol:14 No:08 2020 Vol:14 No:07 2020 Vol:14 No:06 2020 Vol:14 No:05 2020 Vol:14 No:04 2020 Vol:14 No:03 2020 Vol:14 No:02 2020 Vol:14 No:01 2020
Vol:13 No:12 2019 Vol:13 No:11 2019 Vol:13 No:10 2019 Vol:13 No:09 2019 Vol:13 No:08 2019 Vol:13 No:07 2019 Vol:13 No:06 2019 Vol:13 No:05 2019 Vol:13 No:04 2019 Vol:13 No:03 2019 Vol:13 No:02 2019 Vol:13 No:01 2019
Vol:12 No:12 2018 Vol:12 No:11 2018 Vol:12 No:10 2018 Vol:12 No:09 2018 Vol:12 No:08 2018 Vol:12 No:07 2018 Vol:12 No:06 2018 Vol:12 No:05 2018 Vol:12 No:04 2018 Vol:12 No:03 2018 Vol:12 No:02 2018 Vol:12 No:01 2018
Vol:11 No:12 2017 Vol:11 No:11 2017 Vol:11 No:10 2017 Vol:11 No:09 2017 Vol:11 No:08 2017 Vol:11 No:07 2017 Vol:11 No:06 2017 Vol:11 No:05 2017 Vol:11 No:04 2017 Vol:11 No:03 2017 Vol:11 No:02 2017 Vol:11 No:01 2017
Vol:10 No:12 2016 Vol:10 No:11 2016 Vol:10 No:10 2016 Vol:10 No:09 2016 Vol:10 No:08 2016 Vol:10 No:07 2016 Vol:10 No:06 2016 Vol:10 No:05 2016 Vol:10 No:04 2016 Vol:10 No:03 2016 Vol:10 No:02 2016 Vol:10 No:01 2016
Vol:9 No:12 2015 Vol:9 No:11 2015 Vol:9 No:10 2015 Vol:9 No:09 2015 Vol:9 No:08 2015 Vol:9 No:07 2015 Vol:9 No:06 2015 Vol:9 No:05 2015 Vol:9 No:04 2015 Vol:9 No:03 2015 Vol:9 No:02 2015 Vol:9 No:01 2015
Vol:8 No:12 2014 Vol:8 No:11 2014 Vol:8 No:10 2014 Vol:8 No:09 2014 Vol:8 No:08 2014 Vol:8 No:07 2014 Vol:8 No:06 2014 Vol:8 No:05 2014 Vol:8 No:04 2014 Vol:8 No:03 2014 Vol:8 No:02 2014 Vol:8 No:01 2014
Vol:7 No:12 2013 Vol:7 No:11 2013 Vol:7 No:10 2013 Vol:7 No:09 2013 Vol:7 No:08 2013 Vol:7 No:07 2013 Vol:7 No:06 2013 Vol:7 No:05 2013 Vol:7 No:04 2013 Vol:7 No:03 2013 Vol:7 No:02 2013 Vol:7 No:01 2013
Vol:6 No:12 2012 Vol:6 No:11 2012 Vol:6 No:10 2012 Vol:6 No:09 2012 Vol:6 No:08 2012 Vol:6 No:07 2012 Vol:6 No:06 2012 Vol:6 No:05 2012 Vol:6 No:04 2012 Vol:6 No:03 2012 Vol:6 No:02 2012 Vol:6 No:01 2012
Vol:5 No:12 2011 Vol:5 No:11 2011 Vol:5 No:10 2011 Vol:5 No:09 2011 Vol:5 No:08 2011 Vol:5 No:07 2011 Vol:5 No:06 2011 Vol:5 No:05 2011 Vol:5 No:04 2011 Vol:5 No:03 2011 Vol:5 No:02 2011 Vol:5 No:01 2011
Vol:4 No:12 2010 Vol:4 No:11 2010 Vol:4 No:10 2010 Vol:4 No:09 2010 Vol:4 No:08 2010 Vol:4 No:07 2010 Vol:4 No:06 2010 Vol:4 No:05 2010 Vol:4 No:04 2010 Vol:4 No:03 2010 Vol:4 No:02 2010 Vol:4 No:01 2010
Vol:3 No:12 2009 Vol:3 No:11 2009 Vol:3 No:10 2009 Vol:3 No:09 2009 Vol:3 No:08 2009 Vol:3 No:07 2009 Vol:3 No:06 2009 Vol:3 No:05 2009 Vol:3 No:04 2009 Vol:3 No:03 2009 Vol:3 No:02 2009 Vol:3 No:01 2009
Vol:2 No:12 2008 Vol:2 No:11 2008 Vol:2 No:10 2008 Vol:2 No:09 2008 Vol:2 No:08 2008 Vol:2 No:07 2008 Vol:2 No:06 2008 Vol:2 No:05 2008 Vol:2 No:04 2008 Vol:2 No:03 2008 Vol:2 No:02 2008 Vol:2 No:01 2008
Vol:1 No:12 2007 Vol:1 No:11 2007 Vol:1 No:10 2007 Vol:1 No:09 2007 Vol:1 No:08 2007 Vol:1 No:07 2007 Vol:1 No:06 2007 Vol:1 No:05 2007 Vol:1 No:04 2007 Vol:1 No:03 2007 Vol:1 No:02 2007 Vol:1 No:01 2007