Your search keyword '"syntrophic oxidation"' showing total 4 results

1. Exploring the roles of and interactions among microbes in dry co-digestion of food waste and pig manure using high-throughput 16S rRNA gene amplicon sequencing

Author

Jiang, Yan, Dennehy, Conor, Lawlor, Peadar G., Hu, Zhenhu, McCabe, Matthew, Cormican, Paul, Zhan, Xinmin, and Gardiner, Gillian E.

Published

2019

2. Energy recovery and pathogen inactivation with dry co-digestion of food waste and pig manure

Author

Jiang, Yan, Zhan, Xinmin, Lawlor, Peadar, Gardiner, Gillian, and Science Foundation Ireland

Subjects

E. coli, dry digestion, Co-digestion, volatile fatty acid (VFA) inhibition, Civil Engineering, pig manure, enterococci, food waste, minimum inhibitory concentration (MIC), Salmonella, total coliforms, hydrogenotrophic methanogenesis, syntrophic oxidation, inoculum, Engineering and Informatics

Abstract

Anaerobic digestion is one of the best available technologies for food waste (FW) and pig manure (PM) management by producing methane-rich biogas. However, mono digestion of FW or PM is easily inhibited by high volatile fatty acid (VFA) or ammonia. Co-digestion of FW and PM can provide an effective solution to address these issues due to the buffering interactions between the VFA and ammonia. Compared with wet digestion, dry digestion can reduce the digester volume significantly, thereby decreasing initial capital expenditure and the energy consumption required for heating. In this research, batch dry co-digestion of FW and PM was conducted in laboratory-scale digesters at the total solid (TS) content of 20%. The research objectives were to assess (1) the feasibility and optimal operation conditions of dry co-digestion systems; (2) methane production kinetics and the inhibition mechanisms; (3) the biosafety of digestate, i.e. the inactivation of enteric indicator bacteria, including total coliforms, E. coli, enterococci and Salmonella; and (4) microbial community structure evolution in dry co-digestion systems. The results showed that preferable operation conditions were obtained at a digestate inoculum rate of 50% and a FW/PM ratio of 50:50, with an average specific methane yield (SMY) of 252 mL/g VSadded (volatile solids). Using digestate as inoculum didn’t increase the total amount of SMY but significantly decreased the lag phase from 28 days to 13 days compared with using dewatered anaerobic sludge as inoculum. Total VFA was the main inhibition factor on methane production (P VFA concentration > VFA type > Salmonella serotype; and in ammonia MIC tests, the inhibitory effect sequence was in the order of ammonia concentration > pH > Salmonella serotype. At the same concentration, the inhibition effect of VFA was much greater than that of ammonia. The inoculum was more significant in determining the microbial community structure than the FW/PM ratio. Hydrogenotrophic methanogenesis was an important methane production pathway, with Methanoculleus the dominant methanogen. Significant correlation was observed between the relative abundance of specific microbial taxa and digesters’ physicochemical parameters. Based on correlation analysis, the dry co-digestion associated functions of some previously poorly reported bacteria were predicted here for the first time. The results in this study indicate that dry co-digestion of FW and PM is an effective way for treatment of both substrates, with recovery of methane-rich biogas and safe digestate. The data obtained can provide guidance for on-farm engineering practice. The preliminary prediction on the functionality of previously poorly described bacteria will provide reference for further study.

Published

2019

3. Food waste and sewage sludge co-digestion amended with different biochars: VFA kinetics, methane yield and digestate quality assessment.

Author

Johnravindar, Davidraj, Wong, Jonathan W.C., Chakraborty, Debkumar, Bodedla, Govardhan, and Kaur, Guneet

Subjects

*SEWAGE sludge, *AGRICULTURAL wastes, *SEWAGE sludge digestion, *BIOCHAR, *METHANE, *ANAEROBIC digestion, *FOOD quality

Abstract

This work investigated the impact of the addition of different biochar types on mitigation of volatile fatty acid (VFA) accumulation, methane recovery and digestate quality in mesophilic food waste-sludge co-digestion. Four biochars derived from agricultural and sludge residues under different pyrolysis temperatures were compared. Specific biochar properties such as pH, surface area, chemical properties and presence of surface functional groups likely influenced biochar reactions during digestion, thereby resulting in a varying performance of different biochars. Miscanthus straw biochar addition led to the highest specific methane yield of 307 ± 0.3 mL CH 4 /g VS added versus 241.87 ± 5.9 mL CH 4 /g VS added from control with no biochar addition over 30 days of the co-digestion period. Biochar supplementation led to enhanced process stability which likely resulted from improved syntrophic VFA oxidation facilitated by specific biochar properties. Overall, a 21.4% increase in the overall methane production was obtained with biochar addition as compared to control. The resulting digestate quality was also investigated. Biochar-amended digester generated a digestate rich in macro- and micro-nutrients including K, Mg, Ca, Fe making biochar-amended digestate a potential replacement of agricultural lime fertilizer. This work demonstrated that the addition of specific biochars with desirable properties alleviated VFA accumulation and facilitated enhanced methane recovery, thereby providing a means to achieve process stability even under high organic loading conditions in co-digestions. Moreover, the availability of biochar-enriched digestate with superior characteristics than biochar-free digestate adds further merit to this process. [Display omitted] • Effect of various biochar on mesophilic food waste/sludge co-digestion was compared. • Biochar properties influenced their reactions during digestion. • Miscanthus straw biochar resulted in 21.4% increase in specific methane yield. • Biochar-amended (co)digestate was rich in macro- and micro-nutrients. [ABSTRACT FROM AUTHOR]

Published

2021

4. Enhanced volatile fatty acid degradation and methane production efficiency by biochar addition in food waste-sludge co-digestion: A step towards increased organic loading efficiency in co-digestion.

Author

Kaur, Guneet, Johnravindar, Davidraj, and Wong, Jonathan W.C.

Subjects

*METHANE as fuel, *FATTY acids, *PROPIONIC acid, *AGRICULTURAL wastes, *BUTYRIC acid, *METHANE

Abstract

• Effects of biochar on mesophilic food waste/sludge co-digestion were investigated. • Wheat straw biochar resulted in 24% increase in specific methane yield. • Improved VFA degradation was correlated with enhanced methane generation. • Enhanced propionic acid and long-chain VFA degradation was observed. This work investigated the effect of biochar addition to mitigate VFA accumulation and enhance methane production in mesophilic food waste/sludge co-digestion. Different types of biochar derived from agricultural and forestry residues at two pyrolysis temperatures were tested. Results showed that wheat straw biochar 550 °C supported the highest specific methane yield of 381.9 LCH 4 /kg VS added and VS removal efficiency of 41.62% among all treatments. Degradation of propionic acid and long-chain fatty acids such as valeric, caproic and isovaleric acids was observed. This also corresponded to an increase in methanogenic favorable substrates including acetic acid (>40%) and butyric acid (~20%) over the control. Consequently, a 24% increase in overall methane production was obtained as compared to control. This demonstrated that biochar addition had positive effects on VFA degradation and methane production which could be a useful strategy to increase the organic loading in co-digestions without the fear of process failure. [ABSTRACT FROM AUTHOR]

Published

2020