Enhanced denitrification driven by a novel iron-carbon coupled primary cell: chemical and mixotrophic denitrification

IF 13.1 2区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES
Biochar Pub Date : 2024-01-10 DOI:10.1007/s42773-023-00274-2
Ruofan Wu, Paramsothy Jeyakumar, Nanthi Bolan, Xu Zhai, Hailong Wang, Minghui Pan, Jiapan Lian, Liping Cheng, Jiangzhou Li, Minghei Hou, Yonghe Cui, Xiaoe Yang, Kuai Dai
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Abstract

Iron-carbon micro-electrolysis system is a promising method for promoting electron transfer in nitrate removal. However, many traditional approaches involving simple physical mixing inevitably suffered from the confined iron-carbon contact area and short validity period, leading to the overuse of iron. Here, a ceramsite-loaded microscale zero-valent iron (mZVI) and acidified carbon (AC) coupled-galvanic cell (CMC) was designed to support chemical, autotrophic and heterotrophic denitrification. Long-term experiments were conducted to monitor the nitrogen removal performance of denitrification reactors filled with CMC and thus optimized the denitrification performance by improving fabrication parameters and various operating conditions. The denitrification contributions test showed that the chemical denitrification pathway contributed most to nitrate removal (57.3%), followed by autotrophic (24.6%) and heterotrophic denitrification pathways (18.1%). The microbial analysis confirmed the significant aggregation of related denitrifying bacteria in the reactors, while AC promoted the expression of relevant nitrogen metabolism genes because of accelerated uptake and utilization of iron complexes. Meanwhile, the electrochemical analysis revealed a significantly improved electron transfer capacity of AC compared to pristine carbon. Overall, our study demonstrated the application of a novel mZVI-AC coupled material for effective nitrate removal and revealed the potential impact of CMC in the multipathway denitrification process.

Graphical Abstract

Abstract Image

新型铁碳耦合原电池驱动的强化反硝化作用:化学和混养反硝化作用
铁碳微电解系统是一种在硝酸盐去除过程中促进电子转移的有效方法。然而,许多涉及简单物理混合的传统方法不可避免地受到铁碳接触面积有限和有效期短的影响,导致铁的过度使用。在此,我们设计了一种陶瓷负载的微尺度零价铁(mZVI)和酸化碳(AC)耦合电镀池(CMC),以支持化学、自养和异养反硝化作用。通过长期实验监测了填充 CMC 的反硝化反应器的脱氮性能,并通过改进制造参数和各种操作条件优化了反硝化性能。反硝化贡献测试表明,化学反硝化途径对硝酸盐去除的贡献最大(57.3%),其次是自养反硝化途径(24.6%)和异养反硝化途径(18.1%)。微生物分析证实,相关反硝化细菌在反应器中大量聚集,而交流电由于加速了铁络合物的吸收和利用,促进了相关氮代谢基因的表达。同时,电化学分析表明,与原始碳相比,AC 的电子传递能力明显提高。总之,我们的研究证明了新型 mZVI-AC 耦合材料在有效去除硝酸盐方面的应用,并揭示了 CMC 在多途径脱氮过程中的潜在影响。
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来源期刊
Biochar
Biochar Multiple-
CiteScore
18.60
自引率
10.20%
发文量
61
期刊介绍: Biochar stands as a distinguished academic journal delving into multidisciplinary subjects such as agronomy, environmental science, and materials science. Its pages showcase innovative articles spanning the preparation and processing of biochar, exploring its diverse applications, including but not limited to bioenergy production, biochar-based materials for environmental use, soil enhancement, climate change mitigation, contaminated-environment remediation, water purification, new analytical techniques, life cycle assessment, and crucially, rural and regional development. Biochar publishes various article types, including reviews, original research, rapid reports, commentaries, and perspectives, with the overarching goal of reporting significant research achievements, critical reviews fostering a deeper mechanistic understanding of the science, and facilitating academic exchange to drive scientific and technological development.
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