Wenjuan Han

Responses of Dissimilatory Nitrate Reduction to Ammonium and Denitrification to Plant Presence, Plant Species and Species Richness in Simulated Vertical Flow Constructed Wetlands

This study investigated the effects of plant presence, plant species and their species richness on plant biomass production, pH, dissolved oxygen (DO), oxidation-reduction potential (ORP), denitrification (DNF), dissimilatory NO3− reduction to ammonium (DNRA) and two associated bacterial community compositions in thirty vertical flow microcosm wetlands fed with the Hoagland solution, where three plant species richness levels (i.e. unvegetated, monocultured and 4-species polycultured treatment, respectively) were established using four macrophytes. Plant presence increased DO and ORP values, as well as the terminal restriction fragment (TRF) richness and Shannon-Weaver index of the DNRA community and also improved both potential DNF and DNRA rates. The microcosms monocultured with Cyperus alternifolius exhibited the greatest DO, ORP, smallest plant biomass parameters and DNF rates among all of the monocultured microcosms, whereas the microcosms monocultured with Canna glauca and Iris pseudacorus harbored the smallest pH, DO, ORP, the greatest plant biomass parameters and DNRA rates. Compared to both unvegetated and monocultured treatments, the 4-species polycultured treatment was effective in increasing both potential DNF and DNRA rates due to the greatest plant biomass parameters as confirmed by the correlation analysis, but was ineffective in terms of changing both DNF and DNRA community compositions.

Effects of plant diversity on greenhouse gas emissions in microcosms simulating vertical constructed wetlands with high ammonium loading

Wastewater with relatively high nitrogen concentrations is a major source of nitrous oxide (N2O) and methane (CH4) emissions and exerts multiple stresses on the environment. Studies have shown that plant diversity plays an important role in ecosystem functioning. However, the effects of plant species diversity on CH4 and N2O emissions under high ammonium (NH4+-N) loading rates remain unclear. In this study, a microcosm experiment simulating vertical constructed wetlands supplied with high NH4+-N water levels was established. The treatments included four species richness levels (1, 2, 3, 4) and 15 species compositions. There was no significant relationship between species richness and N2O emissions. However, N2O emissions were significantly reduced by specific plant species composition. Notably, the communities with the presence of Rumex japonicus L. reduced N2O emissions by 62% compared to communities without this species. This reduction in N2O emissions may have been a result of decreased N concentrations and increased plant biomass. CH4 emissions did not respond to plant species richness or species identity. Overall, plant species identity surpassed species richness in lowering N2O emissions from constructed wetlands with high NH4+-N water. The results also suggest that communities with R. japonicus could achieve higher N removal and lower greenhouse gas emissions than other wetland species.

Fungal Denitrification Activity in Vertical Flow Constructed Wetlands as Impacted by Plant Species Richness, Carbon, Nitrogen and pH Amendments

To control potential fungal denitrification rate (PFDR) in vertical flow simulated wetlands (VFSW) microcosms, thirty VFSW microcosms were established and planted with three plant species richness levels (i.e. unplanted, monoculture, and four-species polyculture treatment), and effects of carbon, nitrogen and pH amendments on the PFDR were investigated using a room-incubating method. Among seven carbon compounds, sodium citrate, glycerol, glucose and sodium succinate were more effective in enhancing PFDRs. These enhanced effects were dependant on a given species richness level. Sodium nitrite mostly stimulated PFDRs to a greater extent than the other three nitrogen compound amendments at any richness level. Treatments with pH 5.6 or 8.4 had significantly greater PFDRs than the treatment with pH 2.8 in the three species richness levels. However, no effect of plant species richness on the PFDR was observed among any carbon, nitrogen and pH amendments. Current results suggest carbon, nitrogen and pH factors should be considered when mediating fungal denitrification in VFSW microcosms.