Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing, 100085, China; Centre for Water Systems, Department of Engineering, College of Engineering, Mathematics and Physical Sciences, University of Exeter, Exeter, EX4 4QF, United Kingdom; State Key Joint Laboratory of Environmental Simulation and Pollution Control, Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing, 100085, China.
Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing, 100085, China; University of Chinese Academy of Sciences, Beijing, 100049, China.
Water Res. 2019 May 15;155:193-203. doi: 10.1016/j.watres.2019.02.032. Epub 2019 Feb 27.
Although sludge-converted short-chain fatty acids (SCFAs) are promising feedstocks for biorefineries, it remains challenging to maximise SCFA production by enhancing synergies between chemical/biological hydrolysis and acidogenesis processes while employing a balanced composition of microbial communities to counteract methanogenesis. Herein, stepwise control of fermentation pH and chemical/microbiological composition analysis of fermented sludge were used to probe the underlying mechanisms of SCFA production. Fermentation at pH 11 during the first three days promoted both chemical and microbial hydrolysis of sludge proteins and provided a niche for Anaerobrancaceae sp. to transform soluble protein into SCFAs. When pH was decreased from 11 to 9, Acinetobacter, Proteiniborus, Proteiniclasticum, and other acetogens became predominant and stayed significantly more active than during first-stage fermentation at pH 11, which benefited the acidification of hydrolysed substrates. Further assays indicated that early-stage sludge fermentation at pH 11 decreased the total amount of methanogenic archaea and hence reduced the amount of SCFAs consumed for methane production. Thus, the use of stepwise pH control for sludge fermentation allowed one to establish process synergies, facilitate chemical and biological hydrolysis, inhibit methanogens, and promote the growth of acidifying bacterial communities, which resulted in efficient SCFA production from sludge.
尽管污泥转化的短链脂肪酸 (SCFAs) 是生物炼制厂有前途的原料,但通过增强化学/生物水解和产酸过程之间的协同作用,同时采用微生物群落的平衡组成来抵消甲烷生成,以最大限度地提高 SCFA 产量仍然具有挑战性。在此,通过逐步控制发酵 pH 值和对发酵污泥的化学/微生物组成分析,来探究 SCFA 生产的潜在机制。在最初的三天内将 pH 值控制在 11 促进了污泥中蛋白质的化学和微生物水解,并为 Anaerobrancaceae sp. 提供了一个将可溶性蛋白质转化为 SCFAs 的小生境。当 pH 值从 11 降低到 9 时,不动杆菌属、蛋白拟杆菌属、蛋白解淀粉菌属和其他产乙酸菌成为优势菌,并且比在 pH 值为 11 的第一阶段发酵时更为活跃,这有利于水解底物的酸化。进一步的试验表明,在 pH 值为 11 的早期污泥发酵降低了产甲烷古菌的总量,从而减少了用于甲烷生产的 SCFAs 消耗。因此,采用逐步 pH 控制进行污泥发酵可以建立工艺协同作用,促进化学和生物水解,抑制产甲烷菌,并促进酸化细菌群落的生长,从而有效地从污泥中生产 SCFA。
