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Research article - Peer-reviewed, 2022

Atmospheric deposition and precipitation are important predictors of inorganic nitrogen export to streams from forest and grassland watersheds: a large-scale data synthesis

Templer, P. H.; Harrison, J. L.; Pilotto, F.; Flores-Diaz, A.; Haase, P.; McDowell, W. H.; Sharif, R.; Shibata, H.; Blankman, D.; Avila, A.; Baatar, U.; Bogena, H. R.; Bourgeois, I; Campbell, J.; Dirnboeck, T.; Dodds, W. K.; Hauken, M.; Kokorite, I; Lajtha, K.; Lai, I-L;
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Abstract

Previous studies have evaluated how changes in atmospheric nitrogen (N) inputs and climate affect stream N concentrations and fluxes, but none have synthesized data from sites around the globe. We identified variables controlling stream inorganic N concentrations and fluxes, and how they have changed, by synthesizing 20 time series ranging from 5 to 51 years of data collected from forest and grassland dominated watersheds across Europe, North America, and East Asia and across four climate types (tropical, temperate, Mediterranean, and boreal) using the International Long-Term Ecological Research Network. We hypothesized that sites with greater atmospheric N deposition have greater stream N export rates, but that climate has taken a stronger role as atmospheric deposition declines in many regions of the globe. We found declining trends in bulk ammonium and nitrate deposition, especially in the longest time-series, with ammonium contributing relatively more to atmospheric N deposition over time. Among sites, there were statistically significant positive relationships between (1) annual rates of precipitation and stream ammonium and nitrate fluxes and (2) annual rates of atmospheric N inputs and stream nitrate concentrations and fluxes. There were no significant relationships between air temperature and stream N export. Our long-term data shows that although N deposition is declining over time, atmospheric N inputs and precipitation remain important predictors for inorganic N exported from forested and grassland watersheds. Overall, we also demonstrate that long-term monitoring provides understanding of ecosystems and biogeochemical cycling that would not be possible with short-term studies alone.

Keywords

Bulk nitrogen deposition; LTER; Atmospheric pollution; Throughfall; Watershed; Water quality

Published in

Biogeochemistry
2022, Volume: 160, number: 2, pages: 219-241
Publisher: SPRINGER

    Associated SLU-program

    SLU Forest Damage Center

    Sustainable Development Goals

    SDG13 Climate action

    UKÄ Subject classification

    Geosciences, Multidisciplinary
    Meteorology and Atmospheric Sciences
    Environmental Sciences

    Publication identifier

    DOI: https://doi.org/10.1007/s10533-022-00951-7

    Permanent link to this page (URI)

    https://res.slu.se/id/publ/118446