Net N2 fluxes from different lowland ponds draining contrasting land uses in a hilly catchment: Implications for nitrogen removal and its environmental controls

The lowland ponds, depressional submerged areas that are fed by runoff from surrounding uplands and then send overflows to downstream water bodies, are recognized as biogeochemical hotspots of nitrogen (N) removal. Despite their important role in mitigating N pollution, very little is currently known about their potential for N removal, particularly for those ponds draining contrasting land uses. Our study investigated the variabilities of N removal in different types of ponds from a hilly watershed by quantifying gaseous N-2 emission fluxes. The mean excess N-2 concentrations relative to its saturations varied within 0.41-16.44 mu mol L-1, demonstrating that significant N removal occurred in all of the ponds. Further estimates of net N-2 fluxes suggested that ponds impacted by different land use types exhibited distinct potentials for N removal. The ponds that drained tea plantations, which are a typical form of agriculture in hilly regions, had the highest N removal rate (6.48 mmol N-2 m(-2) d(-1)), equivalent to similar to 2.3, 3.0, and 5.8 times those drained by residential areas, mixed-landscape, and forests, respectively. The levels of dissolved oxygen and nutrient supply affected by the different drained land uses were responsible for the different potentials of N removal. Our results suggest that there is a need for integrated management strategies that not only focus on optimization of environmental conditions in ponds but also consider the impacts of the land use compositions in their drainages to more efficiently promote N removal.

Automated summary

This study investigated the variabilities of nitrogen (N) removal in different types of ponds from a hilly watershed and found that ponds impacted by different land use types exhibited distinct potentials for N removal. Ponds draining tea plantations had the highest N removal rate, and the levels of dissolved oxygen and nutrient supply were responsible for the different potentials of N removal. The results suggest the need for integrated management strategies to promote N removal more efficiently.