生物膜
生物量(生态学)
废水
污水处理
硝化作用
环境科学
生化工程
工作(物理)
胞外聚合物
水处理
水力停留时间
生物反应器
制浆造纸工业
环境工程
移动床生物膜反应器
营养物
工艺工程
废物管理
反应堆设计
作者
Yong Fang,Zhiqiang Zhang,Boru Xue,Ying Liu,Kuichuan Sheng
标识
DOI:10.1038/s41467-026-70682-y
摘要
The moving bed biofilm reactor (MBBR) is a cornerstone technology in modern wastewater treatment, yet its performance is often hindered by carrier clogging, which significantly reduces overall treatment efficiency and undermines the technology's environmental benefits. Here, we introduce a V-carrier hydro-topological design strategy that enables biofilm self-regulation, allowing simultaneous control of biofilm thickness and continuous hydraulic shear-induced self-cleaning. In a pure biofilm system treating real municipal wastewater for over 500 days, the V-carrier achieves stable and efficient nutrient removal even under low-temperature (9.1 °C) and high-loading conditions. Crucially, it achieves a 3.2-fold higher unit biomass nitrification rate with a biofilm biomass 44% lower than a conventional K3 carrier, demonstrating that treatment efficiency is decoupled from biomass quantity through optimal ecological niche design. This work establishes a paradigm for biofilm reactor design, transforming carriers from passive substrates into active regulators of microbial ecosystems, with profound implications for sustainable water infrastructure.
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