Reversing inhibition to promotion in phenol-ammonium metabolism via algal-microbial fuel cell: mechanisms of phenol-ammonium interaction and synergistic removal

IF 11.3 1区环境科学与生态学 Q1 ENGINEERING, ENVIRONMENTAL

Journal of Hazardous Materials Pub Date : 2025-04-28 DOI:10.1016/j.jhazmat.2025.138417

Yaqi Liu, Mengqi Zheng, Longyi Lv, Guowei Chen, Chengye Wang, Zhenhu Hu, Jingwei Feng, Binghan Xie, Hongjun Han, Wei Wang

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Abstract

Addressing the challenge of metabolic inhibition between phenol and ammonium in coal gasification wastewater (CGW), this study introduced a novel algal-microbial fuel cell (AMFC). It combined the advantages of electroactive bacteria and Synechocystis to achieve synergistic metabolism, establishing a cooperative mechanism for pollutant separation and enhanced transformation to achieve the mutual promotion of phenol and ammonium removal. Remarkably, raising phenol to 1500 mg COD/L boosted ammonium removal by 31.51% in AMFC, due to a consistently higher potential difference than the control, which enhanced extracellular electron transfer (EET) via conductive nanowire and drove ammonium migration. Similarly, elevating ammonium concentration to 150 mg/L resulted in an 11.79% increase in phenol removal efficiency, driven by superior solution conductivity and EET, as well as more electron acceptors (oxygen) from the algal cathode. This system challenged the conventional understanding of the antagonistic relationship between phenol and ammonium. Under high phenol conditions, the electroactive bacteria Clostridium sensu stricto 1 and Acinetobacter, Perlucidibaca formed a synergistic metabolic network, whereas Zoogloea, Ideonella, and other phenol-degrading bacteria were significantly enriched in high ammonium environments. The AMFC represented a breakthrough in reversing the metabolic inhibition between phenol and ammonium, providing a novel and energy-efficient strategy for treating complex industrial wastewater.

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通过藻类-微生物燃料电池逆转抑制促进苯酚-铵代谢：苯酚-铵相互作用和协同去除的机制

针对煤气化废水中苯酚和铵的代谢抑制问题，提出了一种新型的藻类-微生物燃料电池（AMFC）。结合电活性菌和聚囊菌的优势，实现协同代谢，建立污染物分离和强化转化的协同机制，实现脱酚、脱铵的相互促进。当苯酚浓度提高到1500 mg COD/L时，AMFC的氨氮去除率提高了31.51%，这是由于其电位差持续高于对照组，从而增强了导电纳米线的胞外电子转移（EET），促进了氨氮的迁移。同样，将氨浓度提高到150 mg/L时，苯酚去除效率提高了11.79%，这是由于优异的溶液电导率和EET，以及来自藻类阴极的更多电子受体（氧）。该系统挑战了苯酚和铵之间拮抗关系的传统认识。在高铵环境下，电活性菌Clostridium sensu stricto 1与Acinetobacter、Perlucidibaca形成协同代谢网络，而Zoogloea、Ideonella等酚降解菌在高铵环境下则显著富集。AMFC在逆转苯酚和铵之间的代谢抑制方面取得了突破性进展，为复杂工业废水的处理提供了一种新的节能策略。

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来源期刊

Journal of Hazardous Materials 工程技术-工程：环境

CiteScore

25.40

自引率

5.90%

发文量

3059

审稿时长

58 days

期刊介绍： The Journal of Hazardous Materials serves as a global platform for promoting cutting-edge research in the field of Environmental Science and Engineering. Our publication features a wide range of articles, including full-length research papers, review articles, and perspectives, with the aim of enhancing our understanding of the dangers and risks associated with various materials concerning public health and the environment. It is important to note that the term "environmental contaminants" refers specifically to substances that pose hazardous effects through contamination, while excluding those that do not have such impacts on the environment or human health. Moreover, we emphasize the distinction between wastes and hazardous materials in order to provide further clarity on the scope of the journal. We have a keen interest in exploring specific compounds and microbial agents that have adverse effects on the environment.