Microbial mechanism underlying high methane production of coupled alkali-microwave-H2O2-oxidation pretreated sewage sludge by in-situ bioelectrochemical regulation
2021
Abstract The stabilization and disposal of the large amounts of sewage sludge poses a worldwide challenging problem. To solve this problem, the technical feasibility of coupled alkali-microwave-H2O2-oxidation pretreatment with in-situ bioelectrochemical regulation was used for enhancing sludge biodegradability and methane productivity. The optimum condition of the combined pretreatment was pH 10.0 ± 0.1, microwave 700 W and H2O2 0.4 g/g TS. In this case, soluble chemical oxygen demand (SCOD) of pretreated sludge was increased from initial 330.9 ± 10.0 to 3328.8 ± 49.6 mg/L. The highest accumulative methane yield of 234.3 mL CH4/g VS was obtained for pretreated sludge at the cathodic potential of -0.8 V vs. Ag/AgCl, increasing by 4.3-, and 1.9-fold compared with the raw and pretreated sludge, respectively. The microbial community analysis further provided a compelling evidence that bioelectrochemical regulation stimulated the growth of the functional microorganisms, especially in protein-degrading (Firmicutes), polysaccharides-utilizing (Chloroflexi), electroactive (Geobacter, and Desulfomicrobium) and methane-producing (Methanobacterium) microorganisms. In addition, pH adjustment of pretreated sludge by addition of H2SO4 could further enrich the abundance of microbial community and build a strong syntrophic interaction, accordingly provoking the hydrolysis and subsequent methane production. The result of this study will contribute to the establishment of an efficient sludge stabilization and bioenergy recovery strategy.
Keywords:
- Correction
- Source
- Cite
- Save
- Machine Reading By IdeaReader
63
References
4
Citations
NaN
KQI