纳米零价铁(nZVI)将微生物硝酸盐呼吸从反硝化作用转变为异化硝酸还原成铵(DNRA)处理低碳氮比废水

IF 4.5 Q1 ENVIRONMENTAL SCIENCES ACS ES&T water Pub Date : 2025-04-01 DOI:10.1021/acsestwater.4c01065
Liushi Zheng, Hao Yue, Ximao Wang, Xiaohong Guan* and Yanwen Shen*, 
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摘要

纳米零价铁(nZVI)作为一种替代的电子供体可以驱动硝酸盐还原,以去除或回收废水中的氮。然而,在活性污泥系统中,nZVI是否以及如何控制两个相互竞争的微生物硝酸盐还原过程,即反硝化和异化硝酸盐还原为铵(DNRA),仍然是未知的。本文通过对不同C/N比、不同nZVI用量下的反硝化污泥进行批量试验,在C/N比为2、nZVI用量为1000 mg/L时,硝酸盐-铵效率最高可达97.0%,硝酸盐还原率为15.2 mg N/L/h。虽然nZVI驱动的DNRA在大范围C/N比(1-10)内主导微生物硝酸盐还原,但高nZVI剂量会导致细胞损伤。宏基因组和转录组分析表明,DNRA细菌(如Desulfobulbus, Geobacter, Nitrospira)在nZVI存在下增殖,DNRA在反硝化作用中具有优势,nrfA/H上调,nirS, norB和nosZ基因下调。通过胞外电子转移从Fe(0)中获取电子的毛组装和铁呼吸细菌可能会增强硝酸盐与铵的相互作用。本研究证明了nZVI可以通过调节活性污泥群落来调节微生物硝酸盐还原,从而为低碳氮比废水中铵的回收提供了一条可行的途径。
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Nano-Zerovalent Iron (nZVI) Shifts Microbial Nitrate Respiration from Denitrification to Dissimilatory Nitrate Reduction to Ammonium (DNRA) for the Treatment of Low-C/N Wastewater

Nano-zerovalent iron (nZVI) as an alternative electron donor could drive nitrate reduction for nitrogen removal or recovery from wastewater. However, whether and how nZVI governs the two competing microbial nitrate-reducing processes, namely, denitrification and dissimilatory nitrate reduction to ammonium (DNRA), remains unknown in activated sludge systems. Here, through batch experiments using denitrifying sludge under varied C/N ratios and nZVI doses, a maximum nitrate-to-ammonium efficiency of 97.0% with a nitrate-reducing rate of 15.2 mg N/L/h was achieved at a C/N ratio of 2 and nZVI dose of 1000 mg/L. While nZVI-driven DNRA dominated microbial nitrate reduction over a wide range of C/N ratios (1–10), high nZVI doses caused cellular damage. Metagenome and transcriptome analyses indicated the proliferation of DNRA bacteria (e.g., Desulfobulbus, Geobacter, Nitrospira) in the presence of nZVI and the predominance of DNRA over denitrification with upregulated nrfA/H and downregulated nirS, norB, and nosZ genes. Enhanced nitrate-to-ammonium interaction might potentially benefit from pili-assembling and iron-respiring bacteria that acquire electrons from Fe(0) via extracellular electron transfer. This work proved that nZVI could regulate microbial nitrate reduction by modulating the activated sludge communities and, therefore, provided a feasible route to recover ammonium from low-C/N wastewater.

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