Nitrogen supply differentially affects litter decomposition rates and nitrogen dynamics of sub-arctic bog species.

High-latitude peatlands are important soil carbon sinks. In these ecosystems, the mineralization of carbon and nitrogen are constrained by low temperatures and low nutrient concentrations in plant litter and soil organic matter. Global warming is predicted to increase soil N availability for plants...

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Bibliographic Details
Published in:Oecologia
Main Authors: Aerts, R., van Logtestijn, R.S.P, Karlsson, P.S.
Format: Article in Journal/Newspaper
Language:English
Published: 2006
Subjects:
Arctic
Betula nana
Empetrum nigrum
Eriophorum
Global warming
Northern Sweden
Rubus chamaemorus
Online Access:https://research.vu.nl/en/publications/57332215-0244-4049-8c54-66b959596749
https://doi.org/10.1007/s00442-005-0247-5
https://hdl.handle.net/1871.1/57332215-0244-4049-8c54-66b959596749
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Summary:High-latitude peatlands are important soil carbon sinks. In these ecosystems, the mineralization of carbon and nitrogen are constrained by low temperatures and low nutrient concentrations in plant litter and soil organic matter. Global warming is predicted to increase soil N availability for plants at high-latitude sites. We applied N fertilizer as an experimental analogue for this increase. In a three-year field experiment we studied N fertilization effects on leaf litter decomposition and N dynamics of the four dominant plant species (comprising >75% of total aboveground biomass) in a sub-arctic bog in northern Sweden. The species were Empetrum nigrum (evergreen shrub), Eriophorum vaginatum (graminoid), Betula nana (deciduous shrub) and Rubus chamaemorus (perennial forb). In the controls, litter mass loss rates increased in the order: Empetrum < Eriophorum < Betula < Rubus. Increased N availability had variable, species-specific effects: litter mass loss rates (expressed per unit litter mass) increased in Empetrum, did not change in Eriophorum and Betula and decreased in Rubus. In the leaf litter from the controls, we measured no or only slight net N mineralization even after three years. In the N-fertilized treatments we found strong net N immobilization, especially in Eriophorum and Betula. This suggests that, probably owing to substantial chemical and/or microbial immobilization, additional N supply does not increase the rate of N cycling for at least the first three years. © Springer-Verlag 2005.

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