N2O emission reduction in the biological nitrogen removal process for wastewater with low C/N ratios: mechanisms and strategies.

Urban wastewater, as the main influent type of Waste Water Treatment Plants (WWTPs), has the characteristic of low carbon to nitrogen ratio (C/N). In the biological nitrogen removal (BNR) process, insufficient carbon source often affects the nitrogen removal efficiency and leads to more N2O emissions. We review recent researches on N2O emissions in the BNR process of wastewater with low C/N. The availability of carbon sources affects heterotrophic denitrification (HD) and autotrophic nitrification/denitrification processes, which are the main reasons for N2O emissions in BNR. For the sustainable development of BNR in WWTPs, we introduce strategies suitable for reducing N2O emissions in the BNR process of low C/N wastewater from two aspects: traditional process innovation and new process development. These strategies mainly include carbon source addition, adjustment of aeration strategy, optimization of oxidation ditch and biofilm facilities, and application of Anammox related processes. In the future, it is still necessary to further deepen this research direction through the normalization of N2O emission quantification standards, exploration of N2O metabolism mechanisms, assessment of environmental effects of emission reduction strategies, and practical application of new processes.

The effects, mechanisms, and applications of sulfide as both an inhibitor and electron donor in novel biological nitrogen removal process.

The impacts of sulfide on biological nitrogen removal have been investigated repeatedly, but the impacts in terms of the removal technologies have not been systematically organized and discussed yet. This review recapped the dual character of sulfide in novel biological nitrogen removal and proposed the coupling mechanisms of nitrogen removal and sulfide interaction. The dual character of sulfide was basically divided into the advantage as electron donors and the disadvantage as cytotoxic agent to wide bacteria. The positive character of sulfide has been utilized for improving the performances of denitrification and anaerobic ammonium oxidation in laboratory and polit scales. Intriguingly, the sulfide cytotoxicity was feasibly turned into the profit which was to trigger the partial nitrification by selectively inhibiting ammonia oxidizing bacteria and nitrite oxidizing bacteria. Thus, this productive conversion dramatically promoted the importance of sulfide in sewage treatment. In order to maximize the favorable aspect of sulfide utilization, it was crucial to manage the sulfide concentration for fear of the side reactions with untargeted substances. Furthermore, S/N ratio in sewage may be the keystone that decides if sulfide benefits biological nitrogen removal. In sum, our work can facilitate the dialectical development of effective strategies for sulfide utilization in biological nitrogen removal.