Impact of vegetation harvesting on nutrient removal and plant biomass quality in wetland buffer zones

Fertiliser use in agriculture increases the non-point pollution of waters with nitrogen (N) and phosphorus (P). Wetland buffer zones (WBZs) are wetland ecosystems between agricultural lands and water bodies that protect surface waters from non-point source pollution. We assessed how vegetation harve...

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Veröffentlicht in:	Hydrobiologia 2021-08, Vol.848 (14), p.3273-3289
Hauptverfasser:	Jabłońska, E., Winkowska, M., Wiśniewska, M., Geurts, J., Zak, D., Kotowski, W.
Format:	Artikel
Sprache:	eng
Schlagworte:	Agricultural ecosystems Agricultural land Aquatic ecosystems Biomass Biomedical and Life Sciences Buffer zones Buffers (chemistry) Decomposition Ecology Ecosystems Efficiency Fens Freshwater & Marine Ecology Harvest Leaching Life Sciences Mineral nutrients Mowing Nitrogen Non-point source pollution Nonpoint source pollution Nutrient removal Nutrient uptake Nutrients Phosphorus Plant biomass Plants Plants (botany) Point source pollution Pollution sources Protection and preservation Removal Surface water Surveys Uptake Vegetation Water chemistry Water pollution Wetland Ecosystems Wetlands Zoology
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container_end_page	3289
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creator	Jabłońska, E. Winkowska, M. Wiśniewska, M. Geurts, J. Zak, D. Kotowski, W.
description	Fertiliser use in agriculture increases the non-point pollution of waters with nitrogen (N) and phosphorus (P). Wetland buffer zones (WBZs) are wetland ecosystems between agricultural lands and water bodies that protect surface waters from non-point source pollution. We assessed how vegetation harvesting within WBZs impacts their N and P removal efficiency, nutrient uptake by plants and their biomass quality. We surveyed vegetation of a spontaneously rewetted fen along a small river in Poland, and analysed plant biomass, its nutrient contents and nutrient-leaching potential and the water chemistry. Total N removal reached 34–92% and total P removal 17–63%. N removal was positively related to the initial N concentration, regardless of mowing status. We found a high N removal efficiency (92%) in the harvested site. Vegetation of mown sites differed from that of unmown sites by a higher water-leached carbon and P contents in the biomass. We found that vegetation harvesting may stimulate the overall N removal, but may increase potential biomass decomposability, which eases the recycling of plant-incorporated nutrients back to WBZ. Thus, mowing should always be followed by the removal of biomass. Neglecting already mown WBZs may temporarily lower their nutrient removal efficiency due to potentially faster decomposition of plant biomass.
doi_str_mv	10.1007/s10750-020-04256-4
format	Article
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Wetland buffer zones (WBZs) are wetland ecosystems between agricultural lands and water bodies that protect surface waters from non-point source pollution. We assessed how vegetation harvesting within WBZs impacts their N and P removal efficiency, nutrient uptake by plants and their biomass quality. We surveyed vegetation of a spontaneously rewetted fen along a small river in Poland, and analysed plant biomass, its nutrient contents and nutrient-leaching potential and the water chemistry. Total N removal reached 34–92% and total P removal 17–63%. N removal was positively related to the initial N concentration, regardless of mowing status. We found a high N removal efficiency (92%) in the harvested site. Vegetation of mown sites differed from that of unmown sites by a higher water-leached carbon and P contents in the biomass. 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zones</atitle><jtitle>Hydrobiologia</jtitle><stitle>Hydrobiologia</stitle><date>2021-08-01</date><risdate>2021</risdate><volume>848</volume><issue>14</issue><spage>3273</spage><epage>3289</epage><pages>3273-3289</pages><issn>0018-8158</issn><eissn>1573-5117</eissn><abstract>Fertiliser use in agriculture increases the non-point pollution of waters with nitrogen (N) and phosphorus (P). Wetland buffer zones (WBZs) are wetland ecosystems between agricultural lands and water bodies that protect surface waters from non-point source pollution. We assessed how vegetation harvesting within WBZs impacts their N and P removal efficiency, nutrient uptake by plants and their biomass quality. We surveyed vegetation of a spontaneously rewetted fen along a small river in Poland, and analysed plant biomass, its nutrient contents and nutrient-leaching potential and the water chemistry. Total N removal reached 34–92% and total P removal 17–63%. N removal was positively related to the initial N concentration, regardless of mowing status. We found a high N removal efficiency (92%) in the harvested site. Vegetation of mown sites differed from that of unmown sites by a higher water-leached carbon and P contents in the biomass. We found that vegetation harvesting may stimulate the overall N removal, but may increase potential biomass decomposability, which eases the recycling of plant-incorporated nutrients back to WBZ. Thus, mowing should always be followed by the removal of biomass. Neglecting already mown WBZs may temporarily lower their nutrient removal efficiency due to potentially faster decomposition of plant biomass.</abstract><cop>Cham</cop><pub>Springer International Publishing</pub><doi>10.1007/s10750-020-04256-4</doi><tpages>17</tpages><oa>free_for_read</oa></addata></record>
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subjects	Agricultural ecosystems Agricultural land Aquatic ecosystems Biomass Biomedical and Life Sciences Buffer zones Buffers (chemistry) Decomposition Ecology Ecosystems Efficiency Fens Freshwater & Marine Ecology Harvest Leaching Life Sciences Mineral nutrients Mowing Nitrogen Non-point source pollution Nonpoint source pollution Nutrient removal Nutrient uptake Nutrients Phosphorus Plant biomass Plants Plants (botany) Point source pollution Pollution sources Protection and preservation Removal Surface water Surveys Uptake Vegetation Water chemistry Water pollution Wetland Ecosystems Wetlands Zoology
title	Impact of vegetation harvesting on nutrient removal and plant biomass quality in wetland buffer zones
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