Convective transport of dissolved gases determines the fate of the greenhouse gases produced in reactive drainage filters.

Mitigation of agricultural nitrogen (N) loss via tile drains using woodchip-based subsurface constructed wetlands seems promising. However, the stochastic nature of drainage discharge and consequent temporal variations in hydraulic loading rates may result in the emission of the greenhouse gases (GHG) nitrous oxide (N 2 O) and methane (CH 4 ) with potentially severe climatic effects that are not yet adequately studied. We investigated the influence of the direction of the convective transport on the net export of GHGs by measuring the two export paths of the gases (emitted and dissolved via the effluent) in six woodchip-based subsurface constructed wetlands with different hydraulic designs (horizontal and vertical up- and downward flow). Emissions ranged from −75.1 to 49.5 μg N 2 O N m −2 h −1 and from −0.28 to 720 mg CH 4 C m −2 h −1 . Dissolved concentrations in the effluent ranged from 0 to 1108 μg N 2 O N L −1 and from 4 to 8452 μg CH 4 C L −1 . Nitrous oxide emissions were negligible; thus, the main export path for N 2 O was as gas dissolved in the effluent. April and December were temporal hotspots for N 2 O production. High CH 4 emissions and high dissolved concentrations were associated with the low hydraulic loading and high temperature occurring during the Danish summer. We found no effect of hydraulic design on the net export of N 2 O, whereas the ratio between CH 4 emissions and net export in the form of dissolved CH 4 via the effluent (the export ratio) was significantly affected. In conclusion, vertical downward flow lowered the export ratio of CH 4 and may be the best hydraulic design, when conditions (i.e. low HLR) facilitate high CH 4 production. [ABSTRACT FROM AUTHOR]