Biogas Production and Microbial Communities in the Anaerobic Digestion of Sewage Sludge Under Hydrothermal Pretreatment with Air and a Catalyst

• Published in: Bioenergy research Vol. 14; no. 3; pp. 828 - 843
• Main Authors: Pham, Van Toi, Wu, Pei-Hsun, Guan, Chung-Yu, Chang, Chia-Chi, Liu, Bo-Liang, Chang, Ching-Yuan, Yu, Chang-Ping
• Format: Journal Article
• Language: English
• Published: New York Springer US 01.09.2021; Springer; Springer Nature B.V
• Subjects: Advertising executives; Anaerobic digestion; Anaerobic microorganisms; Biogas; Biomass energy; Biomedical and Life Sciences; Catalysts; Chemical oxygen demand; Community involvement; Dissolved organic carbon; Hydrothermal pretreatment; Life Sciences; Methane; Microbial activity; Microbiomes; Microorganisms; Oxidation; Plant Breeding/Biotechnology; Plant Ecology; Plant Genetics and Genomics; Plant Sciences; Potassium carbonate; Relative abundance; Residence time distribution; Sewage sludge; Sludge; Sludge digestion; Solubilization; Wet oxidation; Wet oxidation process; Wood Science & Technology; Thermal hydrolysis; catalyst; K; Methane production; Wet air oxidation; CO; Microbial community
• ISSN: 1939-1234; 1939-1242
• DOI: 10.1007/s12155-020-10199-4

Hydrothermal pretreatment (HTP) of sewage sludge (SS) has been shown to improve the subsequent biogas production by anaerobic digestion (AD), but the effect of catalysts on HTP performance was less explored. This study intended to investigate the SS pretreatment by wet air oxidation (WAO) with the addition of K 2 CO 3 as a catalyst on the performance of methane production by AD. WAO was found to improve the solubilization of SS, the soluble chemical oxygen demand, dissolved organic carbon, and total dissolved nitrogen. The methane yield from WAO increased from 202 mL/gVS in with no catalyst added to 277 mL/gVS in with 10 wt% of K 2 CO 3 added at 180 °C with 30 min of residence time. Under this pretreatment condition, the highest methane production rate could achieve 15.8 mL/gVS in  day, and the percentage of methane reached 73%. The structure of the microbial community involved in the AD was affected by the residence time, working gas, and catalyst of the HTP process. The results showed that Bacteroidetes, Bacteroidia, and SC103 were the dominant phylum, class, and genus of bacteria, respectively, of almost all of the samples. In addition, the most abundant archaeal order was Methanosarcinales, while Methanosaeta was the dominant archaeal genus of most of the samples. However, Methanosarcina largely increased the relative abundance, corresponding to the amount of K 2 CO 3 catalyst used. The findings in this study demonstrated the potential use of K 2 CO 3 during WAO of SS and implied the link between shift of methanogen community and the enhanced methane yield in AD.