EMEP Eulerian model for atmospheric transport and deposition of nitrogen species over Europe
References (21)
Parameterization of surface resistances to gaseous dry deposition in regional-scale numerical models
Atmospheric Environment
(1989)- et al.
Evaluated kinetic and photochemical data for atmospheric chemistry
Supplement V, IUPAC subcommittee on gas kinetic data evaluation for atmospheric chemistry
Atmospheric Environment
(1996) Preliminary estimates of sulphur transport and deposition in Europe with a regional scale multi-layer Eulerian model
Coupling of wet scavenging of sulphur to clouds in a numerical weather prediction model
Tellus
(1993)- et al.
Transboundary Air Pollution in Europe
- et al.
A regional scale multi-layer model for the calculation of long term transport and deposition of air pollution in Europe
(1998) Two- and three-dimensional model calculations of photochemistry of the troposphere
High resolution model of the planetary boundary layer
A positive definite advection scheme obtained by non-linear renormalization of the advective fluxes
Monthly Weather Review
(1989)
Cited by (30)
Inferring nitrogen deposition from plant community composition
2013, Ecological IndicatorsCitation Excerpt :While N deposition is stabilising, or even falling in much of the industrialised world, ecosystems carry a legacy of past deposition which will not be quickly reversed. National- and international-scale models of N deposition (Jonson et al., 1998; Smith et al., 2000; Fagerli and Aas, 2008) represent the large-scale distribution of pollution reasonably accurately, but cannot show the local-scale impacts of point sources such as individual industrial or agricultural units. It is these local-scale impacts which are usually the concern of practical conservation management, where the interest is often in the impacts of a specific polluter on an individual designated site.
Can pollution bias peatland paleoclimate reconstruction?
2012, Quaternary Research (United States)Citation Excerpt :In many industrialised regions of the world there are few, if any, peatlands unaffected by anthropogenic pollution. For instance, output from the European Monitoring and Evaluation Programme deposition model (Jonson et al., 1998) shows that almost all of Europe (99.6%) receives nitrogen (N) deposition above the natural background (~ 0.5 kg N ha− 1 yr− 1: Dentener et al., 2006) and a majority (68.6%) receives sufficient for impacts on peatland plants to occur (> 5 kg N ha− 1 yr− 1 critical load lower limit: UNECE, 2010). Some paleoecologically well-studied peatlands receive considerable pollution; for instance, N deposition at Walton Moss in northern England (Barber and Langdon, 2007) is around 18 kg N ha− 1 yr− 1, almost four times the lower limit of the critical load.
First Europe-wide correlation analysis identifying factors best explaining the total nitrogen concentration in mosses
2010, Atmospheric EnvironmentCitation Excerpt :The Unified EMEP model was developed at the Norwegian Meteorological Institute under the EMEP programme. The Unified EMEP model is a development of earlier EMEP models (Berge and Jakobsen, 1998; Fagerli et al., 2004; Jonson et al., 1998; Simpson et al., 2003). The model has been extensively validated against measurements (Fagerli et al., 2003, 2007; Jonson et al., 2006; Simpson et al., 2006a,b, 2007).
Modeling agricultural air quality: Current status, major challenges, and outlook
2008, Atmospheric EnvironmentA comparison of two different approaches for mapping potential ozone damage to vegetation. A model study
2007, Environmental PollutionCitation Excerpt :This work makes use of the EMEP MSC-W Unified Eulerian model, revision rv2_0. This model is a development of earlier EMEP Eulerian models documented in Berge and Jakobsen (1998) and Jonson et al. (1998), and is fully documented in Simpson et al. (2003a) and Fagerli et al. (2004). Briefly, the EMEP model is a 3D Eulerian atmospheric dispersion model for simulating the long-range transport of air pollution over several years.
Deposition and emissions of reactive nitrogen over European forests: A modelling study
2006, Atmospheric Environment