New Zealand Journal of Marine and Freshwater Research abstracts

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Nitrate movement and removal along a shallow groundwater flow path in a riparian wetland within a sheep-grazed pastoral catchment: results of a tracer study

Douglas A. Burns^*
Long Nguyen^†

National Institute of Water and Atmospheric Research Limited
P.O. Box 11 115
Hamilton, New Zealand
email: l.nguyen@niwa.cri.nz
^*Present address: United States Geological Survey,  425 Jordan Road, Troy, NY 12180, United States.  email: daburns@usgs.gov
^†Author for correspondence.

Abstract  The movement and removal of nitrate (NO₃^–) along a groundwater flow path within a riparian wetland was investigated during a 24-day period in late autumn–early winter, using a lithium bromide (LiBr)-potassium nitrate (KNO₃) tracer solution containing 19 200 mg/litre as Br^– and 193.8 mg/litre as NO₃-N. The tracer solution was added as an instantaneous dose of tracer solution at a depth of 10–20 cm to four injection wells in two 1 m² plots within a sheep-grazed pastoral catchment at the Whatawhata Agricultural Research Centre near Hamilton, New Zealand. Bromide and NO₃-N concentrations were measured periodically in: (1) wetland groundwater samples from piezometers installed at 15 and 30 cm depths and located at 30, 60, and 100 cm down gradient from the injection wells; and (2) surface flow samples. Peak concentrations of 50–250 mg/litre of Br^– and 0.2–1.1 mg/litre of NO₃-N were reached within 1–2 days after application at most piezometers. Nitrate concentrations decreased thereafter more sharply than did those of Br^–, resulting in decreased NO₃-N/Br^– ratios from Days 2 through 7. More than 99% of groundwater samples collected after the tracer application had NO₃-N/Br^– less than the value in the tracer solution indicating removal of NO₃-N during transport. Mass flux estimates indicated removal of >90% of added NO₃-N along the 100 cm flow path from the injection, with essentially all of the NO₃^– removed within the first 30 cm of transport. On Days 10 and 24, just after rain events, surface flow from the experimental plots had greatly elevated NO₃-N concentrations that were not accompanied by correspondingly elevated Br^– concentrations, indicating that NO₃-N originating from the surrounding catchment was transported over the wetland surface with little penetration or mixing with wetland groundwater. Despite a significant capacity for NO₃-N removal from shallow groundwater equivalent to an annualised value of 50 kg/ha in these wetland study plots, large amounts of NO₃-N from the catchment are likely to move over the wetland surface during rain events without adequate soil contact time for efficient denitrification and retention.

Keywords  riparian wetlands; nitrate removal; nitrate movement; groundwater; water quality; tracer study; grazing management

M01045 Received 7 June 2001; accepted 29 October 2001
New Zealand Journal of Marine and Freshwater Research, 2002, Vol. 36: 371–385
0028–8330/02/3602–0371 $7.00 © The Royal Society of New Zealand 2002

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