Nitrogen critical loads using biodiversity-related critical limits

Critical loads are widely used in the effects-based assessment of emission reduction policies. While the impacts of acidification have diminished, there is increasing concern regarding the effects of nitrogen deposition on terrestrial ecosystems. In this context much attention has been focussed on e...

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Bibliographic Details
Published in:Environmental pollution (1987) 2011-10, Vol.159 (10), p.2223-2227
Main Authors: Posch, Maximilian, Aherne, Julian, Hettelingh, Jean-Paul
Format: Article
Language:English
Subjects:
acidification
acidity
Applied sciences
Assessments
Atmospheric pollution
Biodiversity
Criteria
critical load
Deposition
Ecosystem
Ecosystems
Environmental Monitoring - methods
Environmental Policy
Environmental Pollutants - analysis
Environmental Pollution - statistics & numerical data
Exact sciences and technology
Hydrogen-Ion Concentration
issues and policy
nitrogen
Nitrogen - analysis
Nutrient nitrogen
Nutrients
Optimal deposition region
Optimal load
Plant biodiversity
Plants (organisms)
Policies
Pollution
receptors
Simple mass balance
sulfur
terrestrial ecosystems
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Summary:Critical loads are widely used in the effects-based assessment of emission reduction policies. While the impacts of acidification have diminished, there is increasing concern regarding the effects of nitrogen deposition on terrestrial ecosystems. In this context much attention has been focussed on empirical critical loads as well as simulations with linked geochemistry–vegetation models. Surprisingly little attention has been paid to adapt the widely used simple mass balance approach. This approach has the well-established benefit of easy regional applicability, while incorporating specified critical chemical criteria to protect specified receptors. As plant occurrence/biodiversity is related to both the nutrient and acidity status of an ecosystem, a single abiotic factor (chemical criterion) is not sufficient. Rather than an upper limit for deposition (i.e., critical load), linked nutrient nitrogen and acidity chemical criteria for plant occurrence result in an ‘optimal’ nitrogen and sulphur deposition envelope. ► Mass balance critical load approaches for nutrient nitrogen remain useful. ► Biodiversity-related limits are related to nutrient and acidity status. ► Nutrient and acidity chemical criteria lead to optimal deposition envelopes. ► Optimal loads support effects-based emission reduction policies. Biodiversity-related critical limits lead to optimal nitrogen and sulphur deposition envelopes for plant species or species compositions.
ISSN:0269-7491
1873-6424
DOI:10.1016/j.envpol.2010.11.001