Zhu Xiaoxiao, Chang Wenjie, Kong Yu, Cai Ying, Huang Zhaoming, Wu Tianqi, Zhang Miao, Nie Huijun, Wang Yuan
Jiangsu Environmental Engineering Technology Co., Ltd, Nanjing 210000, China; Jiangsu Province Engineering Research Center of Synergistic Control of Pollution and Carbon Emissions in Key Industries, Nanjing 210000, China E-mail:
Jiangsu Environmental Engineering Technology Co., Ltd, Nanjing 210000, China; Jiangsu Province Engineering Research Center of Synergistic Control of Pollution and Carbon Emissions in Key Industries, Nanjing 210000, China.
Water Sci Technol. 2024 Dec;90(12):3166-3179. doi: 10.2166/wst.2024.391. Epub 2024 Dec 12.
Moving bed biofilm reactors can purify urban domestic sewage through microbial biodegradation. High-throughput sequencing was used to study the response mechanism of the biofilm microbial community to temperature. The effluent quality of the reactor declined with the decrease in temperature. , , and were the dominant bacteria, accounting for 59.2, 11.9, and 9.4%, respectively. (38.3%), (23.2%), and (12.4%) were the dominant bacteria at the class level. Low temperature had an obvious directional domestication effect on microbial flora, and the composition of the bacterial community was more similar. was one of the dominant bacterial groups at 5 °C. ( < 0.001) and ( < 0.05) were significantly negatively correlated with effluent ammonia nitrogen and significantly positively correlated with NO ( < 0.05) at low temperature. Functional bacteria related to chemoheterotrophy (25.88%) and aerobic_chemoheterotrophy (21.56%) accounted for a relatively high proportion. The bacteria related to nitrate reduction only accounted for 2.62%. Studies have shown that low temperatures can inhibit the growth of nitrogen-cycling bacteria, and few domesticated and selected nitrogen-cycling bacteria play a major role in the removal and transformation of ammonia nitrogen. The degradation of chemical oxygen demand can still be achieved through the adsorption and degradation of dominant functional bacteria.
移动床生物膜反应器可通过微生物生物降解净化城市生活污水。采用高通量测序研究生物膜微生物群落对温度的响应机制。随着温度降低,反应器的出水水质下降。[具体细菌名称1]、[具体细菌名称2]和[具体细菌名称3]是优势菌,分别占59.2%、11.9%和9.4%。[具体细菌类别1](38.3%)、[具体细菌类别2](23.2%)和[具体细菌类别3](12.4%)是类水平上的优势菌。低温对微生物菌群有明显的定向驯化作用,细菌群落组成更相似。[具体细菌名称4]是5℃时的优势菌群之一。在低温下,[具体细菌名称5](P<0.001)和[具体细菌名称6](P<0.05)与出水氨氮显著负相关,与NO(P<0.05)显著正相关。与化学异养(25.88%)和好氧化学异养(21.56%)相关的功能菌占比较高。与硝酸盐还原相关的细菌仅占2.62%。研究表明,低温会抑制氮循环细菌的生长,驯化和筛选出的氮循环细菌很少在氨氮的去除和转化中起主要作用。化学需氧量的降解仍可通过优势功能菌的吸附和降解来实现。
