Phosphorus Fluxes in a Temperate Forested Watershed: Canopy Leaching, Runoff Sources, and In-Stream Transformation

Sohrt, Jakob; Kaiser, Klaus; Lang, Friederike; Krüger, Jaane; Frick, Daniel A.; Uhlig, David; Siemens, Jan; von Blanckenburg, Friedhelm; Seeger, Stefan; Weiler, Markus

doi:10.3389/ffgc.2019.00085

Journal Article

FZJ-2020-00797

Phosphorus Fluxes in a Temperate Forested Watershed: Canopy Leaching, Runoff Sources, and In-Stream Transformation

Sohrt, J. (Corresponding author) ; Uhlig, D.FZJ* ; Kaiser, K. ; von Blanckenburg, F. ; Siemens, J. ; Seeger, S. ; Frick, D. A. ; Krüger, J. ; Lang, F. ; Weiler, M.

2019
Frontiers Media Lausanne

Frontiers in forests and global change 2, 85 (2019) [10.3389/ffgc.2019.00085]

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Please use a persistent id in citations: http://hdl.handle.net/2128/24190 doi:10.3389/ffgc.2019.00085

Abstract: Declining foliar phosphorus (P) levels call increasing attention to the cycling of this element in temperate forests. We explored the fluxes of P in a temperate mixed deciduous forest ecosystem in six distinct hydrological compartments: Bulk precipitation and throughfall, soil water draining laterally from three different soil depths (0–15, 15–150, 150–320 cm below soil surface), groundwater, creek and spring discharge, which were sampled at daily to bi-weekly resolution from March 2015 to February 2016. Atmospheric P fluxes into the ecosystem were equally partitioned between wet and dry deposition. Approximately 10% of the foliar P stock was lost annually by foliar leaching during late summer. The concentrations of dissolved P in soil water from the forest floor and upper mineral topsoil followed a pronounced seasonal cycle with higher concentrations during the vegetation period. The concentrations of P dissolved in soil water decreased with increasing soil depth. Using an end member mixing analysis (EMMA) we found that P sources feeding the spring water were both soil water from greater depths or groundwater with season specific contributions. Atmospheric P fluxes into the ecosystem determined in this study and P-release from weathering reported for the research site were large enough to compensate P losses with runoff. This suggests that declining foliar P levels of forests are unlikely the result of a dwindling total P supply, but rather caused by tree nutrition imbalances or alternative stressors.

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