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Denitrification Potential in Relation to Lithology in Five Headwater Riparian Zones
Author(s) -
Hill Alan R.,
Vidon Philippe G. F.,
Langat Jackson
Publication year - 2004
Publication title -
journal of environmental quality
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.888
H-Index - 171
eISSN - 1537-2537
pISSN - 0047-2425
DOI - 10.2134/jeq2004.0911
Subject(s) - riparian zone , soil water , outwash plain , water table , geology , denitrification , hydrology (agriculture) , lithology , loam , soil science , groundwater , glacial period , geomorphology , geochemistry , nitrogen , ecology , chemistry , habitat , geotechnical engineering , organic chemistry , biology
ABSTRACT The influence of riparian zone lithology on nitrate dynamics is poorly understood. We investigated vertical variations in potential denitrification activity in relation to the lithology and stratigraphy of five headwater riparian zones on glacial till and outwash landscapes in southern Ontario, Canada. Conductive coarse sand and gravel layers occurred in four of the five riparian areas. These layers were thin and did not extend to the field–riparian perimeter in some riparian zones, which limited their role as conduits for ground water flow. We found widespread organic‐rich layers at depths ranging from 40 to 300 cm that resulted from natural floodplain processes and the burial of surface soils by rapid valley‐bottom sedimentation after European settlement. The organic matter content of these layers varied considerably from 2 to 5% (relic channel deposit) to 5 to 21% (buried soils) and 30 to 62% (buried peat). Denitrification potential (DNP) was measured by the acetylene block method in sediment slurries amended with nitrate. The highest DNP rates were usually found in the top 0‐ to 15‐cm surface soil layer in all riparian zones. However, a steep decline in DNP with depth was often absent and high DNP activity occurred in the deep organic‐rich layers. Water table variations in 2000–2002 indicated that ground water only interacted frequently with riparian surface soils between late March and May, whereas subsurface organic layers that sustain considerable DNP were below the water table for most of the year. These results suggest that riparian zones with organic deposits at depth may effectively remove nitrate from ground water even when the water table does not interact with organic‐rich surface soil horizons.