Prairie and Turfgrass Buffer Strips Modify Water Infiltration and Leachate Resulting from Impervious Surface Runoff

Concerns over NO3-N concentrations in drinking water and potential subsurface transport of P to surface waters are driving legislation on precautionary N and P application restrictions on turfgrass areas and in recommendations for vegetative plantings within urban environments. Two plant communities...

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Bibliographic Details
Published in:Crop science 2009-03, Vol.49 (2), p.658-670
Main Authors: Steinke, K, Stier, J.C, Kussow, W.R
Format: Article
Language:English
Subjects:
Agronomy. Soil science and plant productions
Aquatic ecosystems
Biogeochemical cycles
Biological and medical sciences
Contamination
Drainage water
Drinking water
fertilizer rates
filter strips
forbs
Fundamental and applied biological sciences. Psychology
grasses
Groundwater management
Groundwater recharge
infiltration (hydrology)
lawns and turf
Leachates
Legislation
Life sciences
nitrate nitrogen
nitrogen fertilizers
Nutrient cycles
phosphorus
phosphorus fertilizers
Plant communities
Poa pratensis
prairies
runoff
Soil science
Soils
Surface runoff
Surface water
Turf
turf grasses
urban areas
Urban environments
Vegetation
Water protection
Water quality
Water supply
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Summary:Concerns over NO3-N concentrations in drinking water and potential subsurface transport of P to surface waters are driving legislation on precautionary N and P application restrictions on turfgrass areas and in recommendations for vegetative plantings within urban environments. Two plant communities and three impervious:pervious surface ratios were examined for effects on leachate water quantity and quality over a 3-yr period. A Kentucky bluegrass blend (Poa pratensis L.) and a mixed forb and grass prairie were monitored for 3 yr for total leachate volumes, total dissolved N (TDN) loading, and soluble PO4-P loading. Both types of vegetation provided similar annual groundwater recharge rates. Annual TDN losses from fertilized turf and unfertilized prairie were similar during and after establishment, with postestablishment losses averaging 3.6 and 2.2 kg ha-1, respectively. Mean annual soluble PO4-P losses postestablishment were 0.6 and 0.7 kg ha-1 for fertilized turf and unfertilized prairie, respectively. When compared with the absence of a buffer area, pervious surfaces at least one-half the size of impervious surfaces resulted in at least a 50% reduction in drainage water volumes. Fertilized turfgrass and unfertilized prairie vegetation provided similar groundwater protection and recharge abilities, and both resulted in some natural biogeochemical nutrient cycling.
ISSN:0011-183X
1435-0653
DOI:10.2135/cropsci2008.06.0315