Iron-carbon micro-electrolysis facilitates autotrophic denitrification and Feammox in tidal flow constructed wetlands for enhanced nitrogen removal and reduced N2O emissions

[Display omitted] •Novel Fe-C tidal flow system boosts NH4+-N and TN removal in constructed wetlands.•Tidal operation promoted Fe cycling and microbe enrichment, enhancing denitrification.•Fe-C release Fe2+ via galvanic cell reaction to promote denitrification and Feammox.•Notable increase in Fe-red...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2024-04, Vol.486, p.150367, Article 150367
Main Authors: Zhao, Liping, Zheng, Yucong, Wang, Zhenzhen, Zhang, Dongxian, Ma, Duo, Zhao, Yaqian, Wang, Xiaochang C., Chen, Rong, Dzakpasu, Mawuli
Format: Article
Language:English
Subjects:
Autotrophic denitrification
Constructed wetlands
Feammox
Iron-carbon
Tidal flow
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Summary:[Display omitted] •Novel Fe-C tidal flow system boosts NH4+-N and TN removal in constructed wetlands.•Tidal operation promoted Fe cycling and microbe enrichment, enhancing denitrification.•Fe-C release Fe2+ via galvanic cell reaction to promote denitrification and Feammox.•Notable increase in Fe-reducing, autotrophic denitrifying bacteria and gene abundance.•Autotrophic denitrification pathway enhances TN removal while reducing N2O emissions. This study focused on developing a tidal flow constructed wetland (CW) with an iron-carbon (Fe-C) substrate to enhance nitrogen removal efficiency. The results demonstrated significant improvements in the removal of NH4+-N and TN in the iron-carbon tidal flow constructed wetland (IC-TFCW) compared to traditional gravel CW. IC-TFCW achieved a 23.82 % and 31.01 % more effective removal, resulting in reductions of 82.45 % and 74.13 %, respectively. The large specific surface area and electron transfer effect of the Fe-C substrate facilitated pollutant retention and proliferation of denitrifying microorganisms. However, the Fe-C substrate inhibited plant growth and rhizosphere microorganisms, reducing plant nitrogen uptake by 2.69-fold. Galvanic cell reaction in the Fe-C substrate facilitated the release of iron and its oxides and promoted iron cycling under the alternating aerobic-anoxic conditions induced by tidal flow. This led to the enrichment of autotrophic denitrifying and Fe-reducing bacteria by 14.89 and 1.1 times, and increase in the relative abundance of denitrification genes nar (narG, narH, narI) and nap (napA, napB) by 60.94 %. The Fe2+ released during the galvanic cell reaction contributed electrons to denitrification, while the reduction of Fe3+ facilitated the Anammox process, resulting in the Feammox reaction. This created an autotrophic denitrification pathway (autotrophic denitrification and Feammox), synergizing with the heterotrophic denitrification pathway and the iron cycling process to significantly increase TN removal and reduce N2O emissions per unit of TN removed by up to 36.99 %. These findings elucidate the various denitrification pathways present in CW and provide insights into improving denitrification efficiency.
ISSN:1385-8947
DOI:10.1016/j.cej.2024.150367