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Controls on the dynamics of dissolved organic carbon and nitrogen in a Central European deciduous forest

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Abstract

Despite growing attention concerning therole of dissolved organic matter (DOM) inelement cycling of forest ecosystems, thecontrols of concentrations and fluxes of bothdissolved organic carbon (DOC) and nitrogen(DON) under field conditions in forest soilsremain only poorly understood. The goal ofthis project is to measure the concentrations and fluxes of DON, NH4 +, NO3 and DOC in bulkprecipitation, throughfall, forest floorleachates and soil solutions of a deciduousstand in the Steigerwald region (northernBavaria, Germany). The DOC and DONconcentrations and fluxes were highest inleachates originating from the Oa layer of theforest floor (73 mg C L−1, 2.3 mg NL−1 and about 200–350 kg C, 8–10 kg Nha−1 yr−1). They were observed to behighly variable over time and decreased in themineral topsoil (17 mg C L−1, 0.6 mg NL−1 and about 50–90 kg C, 2.0 to 2.4 kg Nha−1 yr−1). The annual variability ofDOC and DON concentrations and subsequentialDOC/DON ratios was substantial in allsolutions. The DOC and DON concentrations inthroughfall were positively correlated withtemperature. The DOC and DON concentrationsdid not show seasonality in the forest floorand mineral soil. Concentrations were notrelated to litterfall dynamics but didcorrespond in part to the input of DOC and DONfrom throughfall. The throughfall contributionto the overall element fluxes was higher forDON than for DOC. Concentrations and fluxes ofDON were significantly correlated to DOC inthroughfall and the Oi layer. However, thecorrelation was weak in Oa leachates. Inaddition, seasonal and annual variation ofDOC/DON ratios indicated different mechanismsand release rates from the forest floor forboth components. The concentrations of DOC andDON in forest floor leachates were in mostcases dependent neither on the pH value orionic strength of the solution, nor on thewater flux or temperature changes. As aconsequence, the DOC and DON fluxes from theforest floor into the mineral soil werelargely dependent on the water flux if annualand biweekly time scales are considered.

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Authors and Affiliations

  1. Department of Soil Ecology, Bayreuth Institute for Terrestrial Ecosystem Research (BITOEK), University of Bayreuth, D-95440, Bayreuth, Germany

    Stephan Solinger & Egbert Matzner

  2. Department of Soil Ecology, Bayreuth Institute for Terrestrial Ecosystem Research (BITOEK), University of Bayreuth, D-95440, Bayreuth, Germany (e-mail

    Karsten Kalbitz

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  1. Stephan Solinger
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Solinger, S., Kalbitz, K. & Matzner, E. Controls on the dynamics of dissolved organic carbon and nitrogen in a Central European deciduous forest. Biogeochemistry 55, 327–349 (2001). https://doi.org/10.1023/A:1011848326013

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