Slow recovery of High Arctic heath communities from nitrogen enrichment

Arctic ecosystems are strongly nutrient limited and exhibit dramatic responses to nitrogen (N) enrichment, the reversibility of which is unknown. This study uniquely assesses the potential for tundra heath to recover from N deposition and the influence of phosphorus (P) availability on recovery. We...

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Bibliographic Details
Published in:The New phytologist 2015-04, Vol.206 (2), p.682-695
Main Authors: Street, Lorna E., Burns, Nancy R., Woodin, Sarah J.
Format: Article
Language:English
Subjects:
Arctic Regions
Atmosphere
Bryophyta - growth & development
Bryophyta - metabolism
bryophytes
Community composition
Composition effects
critical load
Deposition
Dynamics
Ecosystem
Ecosystems
Europe
Mineral nutrients
Nitrogen
nitrogen (N) deposition
Nitrogen - metabolism
Nitrogen enrichment
Nutrient dynamics
Nutrient enrichment
Nutrient status
Phosphorus
phosphorus (P)
Phosphorus - metabolism
Polar environments
Recovery
Tundra
Vegetation
Vegetation effects
winter injury
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Summary:Arctic ecosystems are strongly nutrient limited and exhibit dramatic responses to nitrogen (N) enrichment, the reversibility of which is unknown. This study uniquely assesses the potential for tundra heath to recover from N deposition and the influence of phosphorus (P) availability on recovery. We revisited an experiment in Svalbard, established in 1991, in which N was applied at rates representing atmospheric N deposition in Europe (10 and 50 kg N ha−1 yr−1; ‘low’ and ‘high’, respectively) for 3–8 yr. We investigated whether significant effects on vegetation composition and ecosystem nutrient status persisted up to 18 yr post-treatment. Although the tundra heath is no longer N saturated, N treatment effects persist and are strongly P-dependent. Vegetation was more resilient to N where no P was added, although shrub cover is still reduced in low-N plots. Where P was also added (5 kg P ha−1 yr−1), there are still effects of low N on community composition and nutrient dynamics. High N, with and without P, has many lasting impacts. Importantly, N + P has caused dramatically increased moss abundance, which influences nutrient dynamics. Our key finding is that Arctic ecosystems are slow to recover from even small N inputs, particularly where P is not limiting.
ISSN:0028-646X
1469-8137
DOI:10.1111/nph.13265