TY - JOUR

T1 - Bryophytes and organic layers control uptake of airborne nitrogen in low-N environments

AU - Bähring, Alexandra

AU - Fichtner, Andreas

AU - Friedrich, Uta

AU - Von Oheimb, Goddert

AU - Härdtle, Werner

PY - 2017/12/4

Y1 - 2017/12/4

N2 - The effects of atmospheric nitrogen (N) deposition on ecosystem functioning largely depend on the retention of N in different ecosystem compartments, but accumulation and partitioning processes have rarely been quantified in long-term field experiments. In the present study we analysed for the first time decadal-scale flows and allocation patterns of N in a heathland ecosystem that has been subject to airborne N inputs over decades. Using a long-term15N tracer experiment, we quantified N retention and flows to and between ecosystem compartments (above-ground/below-ground vascular biomass, moss layer, soil horizons, leachate). After 9 years, about 60% of the added15N-tracer remained in the N cycle of the ecosystem. The moss layer proved to be a crucial link between incoming N and its allocation to different ecosystem compartments (in terms of a short-term capture, but long-term release function). However, about 50% of the15N captured and released by the moss layer was not compensated for by a corresponding increase in recovery rates in any other compartment, probably due to denitrification losses from the moss layer in the case of water saturation after rain events. The O-horizon proved to be the most important long-term sink for added15N, as reflected by an increase in recovery rates from 18 to 40% within 8 years. Less than 2.1% of15N were recovered in the podzol-B-horizon, suggesting that only negligible amounts of N were withdrawn from the N cycle of the ecosystem. Moreover,15N recovery was low in the dwarf shrub above-ground biomass (

AB - The effects of atmospheric nitrogen (N) deposition on ecosystem functioning largely depend on the retention of N in different ecosystem compartments, but accumulation and partitioning processes have rarely been quantified in long-term field experiments. In the present study we analysed for the first time decadal-scale flows and allocation patterns of N in a heathland ecosystem that has been subject to airborne N inputs over decades. Using a long-term15N tracer experiment, we quantified N retention and flows to and between ecosystem compartments (above-ground/below-ground vascular biomass, moss layer, soil horizons, leachate). After 9 years, about 60% of the added15N-tracer remained in the N cycle of the ecosystem. The moss layer proved to be a crucial link between incoming N and its allocation to different ecosystem compartments (in terms of a short-term capture, but long-term release function). However, about 50% of the15N captured and released by the moss layer was not compensated for by a corresponding increase in recovery rates in any other compartment, probably due to denitrification losses from the moss layer in the case of water saturation after rain events. The O-horizon proved to be the most important long-term sink for added15N, as reflected by an increase in recovery rates from 18 to 40% within 8 years. Less than 2.1% of15N were recovered in the podzol-B-horizon, suggesting that only negligible amounts of N were withdrawn from the N cycle of the ecosystem. Moreover,15N recovery was low in the dwarf shrub above-ground biomass (

KW - Calluna vulgaris

KW - Critical load

KW - Heathland

KW - Nitrogen cycling

KW - Nitrogen retention

KW - Nitrogen saturation

KW - Biology

UR - http://www.scopus.com/inward/record.url?scp=85038348991&partnerID=8YFLogxK

U2 - 10.3389/fpls.2017.02080

DO - 10.3389/fpls.2017.02080

M3 - Journal articles

C2 - 29375589

AN - SCOPUS:85038348991

VL - 8

JO - Frontiers in Plant Science

JF - Frontiers in Plant Science

SN - 1664-462X

M1 - 2080

ER -