Traditional land use effects on nutrient export from watersheds to coastal seas

Land use features can have a significant impact on the flux and stoichiometry of nutrients from the watershed to the sea along the freshwater continuum. Traditional agricultural watersheds designated as a Globally Important Agricultural Heritage System (GIAHS) may have unique features on nutrient dy...

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Veröffentlicht in:	Nutrient cycling in agroecosystems 2021, Vol.119 (1), p.7-21
Hauptverfasser:	Sugimoto, Ryo, Kasai, Akihide, Tait, Douglas R., Rihei, Takahito, Hirai, Takeru, Asai, Kazuyoshi, Tamura, Yuji, Yamashita, Yoh
Format:	Artikel
Sprache:	eng
Schlagworte:	Agricultural land Agricultural management Agricultural watersheds Agriculture Biomedical and Life Sciences Coastal waters Cultivated lands Denitrification Downstream Forest management Forest soils Generalized linear models Irrigation Isotopes Land use Life Sciences Microorganisms Nitrates Nitrification Nutrient concentrations Nutrient dynamics Nutrients Original Article Phosphorus Residential areas Rice fields Stable isotopes Statistical models Stoichiometry Traditional farming Upstream
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container_title	Nutrient cycling in agroecosystems
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creator	Sugimoto, Ryo Kasai, Akihide Tait, Douglas R. Rihei, Takahito Hirai, Takeru Asai, Kazuyoshi Tamura, Yuji Yamashita, Yoh
description	Land use features can have a significant impact on the flux and stoichiometry of nutrients from the watershed to the sea along the freshwater continuum. Traditional agricultural watersheds designated as a Globally Important Agricultural Heritage System (GIAHS) may have unique features on nutrient dynamics. Here, we conducted seasonal, high-resolution spatial surveys for concentrations of dissolved inorganic phosphorus (DIP) and nitrogen (DIN) and stable isotopes of water and nitrate of the GIAHS in Japan (Kunisaki Peninsula). The highest upstream DIN concentrations (mean = 83 μM) were observed in the non-irrigation period in autumn. 17 O isotopes of nitrate suggested that microbial nitrification in forest soil was the primary source (> 95%) of total nitrate. Spatial differences in DIP and DIN concentrations among the upstream, midstream, and downstream waters were small, with high DIN/DIP ratios (> 50) were exported from the watershed to coastal seas. Nutrient concentrations exhibited different dynamics during summer when irrigation was taking place with average DIP concentrations increasing from upstream (0.5 μM) to downstream (2.1 μM) waters. A generalized linear model showed that the proportion of paddy fields, cultivated land, residential area as well as forest were the primary drivers of DIP concentrations. DIN concentrations decreased moving downstream likely due to denitrification in the anaerobic irrigation ponds and paddy fields. This study showed that the traditional agricultural landscapes mitigated the excess DIN loading from forested areas while supplying the essential DIP for coastal production, suggesting an important forest-river-sea connection system that manages nutrient inputs to coastal waters.
doi_str_mv	10.1007/s10705-020-10102-9
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subjects	Agricultural land Agricultural management Agricultural watersheds Agriculture Biomedical and Life Sciences Coastal waters Cultivated lands Denitrification Downstream Forest management Forest soils Generalized linear models Irrigation Isotopes Land use Life Sciences Microorganisms Nitrates Nitrification Nutrient concentrations Nutrient dynamics Nutrients Original Article Phosphorus Residential areas Rice fields Stable isotopes Statistical models Stoichiometry Traditional farming Upstream
title	Traditional land use effects on nutrient export from watersheds to coastal seas
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