Abstract
We use 23 atmospheric chemistry transport models to calculate current and future
(2030) deposition of reactive nitrogen (NOy, NHx) and sulfate (SOx) to land and ocean
surfaces. The models are driven by three emission scenarios: (1) current air quality
legislation (CLE); (2) an optimistic case of the maximum emissions reductions currently
technologically feasible (MFR); and (3) the contrasting pessimistic IPCC SRES A2
scenario. An extensive evaluation of the present-day deposition using nearly all
information on wet deposition available worldwide shows a good agreement with
observations in Europe and North America, where 60–70% of the model-calculated wet
deposition rates agree to within ±50% with quality-controlled measurements. Models
systematically overestimate NHx deposition in South Asia, and underestimate NOy
deposition in East Asia. We show that there are substantial differences among models for
the removal mechanisms of NOy, NHx, and SOx, leading to ±1 s variance in total
deposition fluxes of about 30% in the anthropogenic emissions regions, and up to a factor
of 2 outside. In all cases the mean model constructed from the ensemble calculations is
among the best when comparing to measurements. Currently, 36–51% of all NOy, NHx,
and SOx is deposited over the ocean, and 50–80% of the fraction of deposition on land
falls on natural (nonagricultural) vegetation. Currently, 11% of the world’s natural
vegetation receives nitrogen deposition in excess of the ‘‘critical load’’ threshold of
1000 mg(N) m 2 yr 1. The regions most affected are the United States (20% of
vegetation), western Europe (30%), eastern Europe (80%), South Asia (60%), East Asia (40%), southeast Asia (30%), and Japan (50%). Future deposition fluxes are mainly
driven by changes in emissions, and less importantly by changes in atmospheric
chemistry and climate. The global fraction of vegetation exposed to nitrogen loads in
excess of 1000 mg(N) m 2 yr 1 increases globally to 17% for CLE and 25% for A2. In
MFR, the reductions in NOy are offset by further increases for NHx deposition. The
regions most affected by exceedingly high nitrogen loads for CLE and A2 are Europe and
Asia, but also parts of Africa.
Original language | Undefined/Unknown |
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Pages (from-to) | GB4003/1-GB4003/21 |
Number of pages | 21 |
Journal | Global Biogeochemical Cycles |
Volume | 20 |
Publication status | Published - 2006 |