On Modeling Dry Deposition of Long-Lived and Chemically Reactive Species over Heterogeneous Terrain

G. Tetzlaff; R. Dlugi; K. Friedrich; G. Gross; D. Hinneburg; U. Pahl; M. Zelger; N. Mölders

doi:10.1023/A:1015740203204

Details

Original language	English
Pages (from-to)	123-155
Number of pages	33
Journal	Journal of atmospheric chemistry
Volume	42
Issue number	1
Publication status	Published - May 2002

Abstract

An explicit multi-layer subgrid-scheme was developed for a meso-γ/β-scale model to consider subgrid-scale surface heterogeneity, dry deposition, biogenic and anthropogenic emission of trace gases. Since dry deposition measurements of highly reactive trace species are scarce we try to evaluate this scheme by heuristic principles. The results of simulations conducted for a 5 × 5 km² resolution with and without this scheme are evaluated by using results of a model run with 1 × 1 km² resolution, which is taken as a 'grand thruth' and which has the same resolution as the subgrid. The explict multi-layer subgrid scheme provides a similar distribution of dry deposition fluxes as the much more computationally expensive simulation with the 1 × 1 km² resolution. Dry deposition fluxes determined from observations give evidence that the explicit multi-layer subgrid scheme which does not require a constant flux approximation for a layer of several decameters leads to an improvement in determining the exchange between the atmosphere and the ground. Results of simulations with a microscale model show that the inhomogeneity at forest edges leads to an increase of the turbulent transports of up to a factor 4 compared to horizontally homogeneous terrain, which is assumed to be the conditions of the subgrid cells (and which is usually the assumption for the entire grid cell in mesoscale models). Inhomogeneity inside an extended stand of trees causes an overall increase of 5-10% with high local extremes, i.e. such an inhomogeneity results to an underestimation of dry deposition in meso-γ/β-scale models. The effects are most pronounced for a wind direction perpendicular to the forest edge.

Keywords

Dry deposition, Explicit multi-layer subgrid scheme, Forest edge, Mesoscale modeling, Microscale modeling, Surface heterogeneity

ASJC Scopus subject areas

Environmental Science(all)
Environmental Chemistry
Earth and Planetary Sciences(all)
Atmospheric Science

Cite this

On Modeling Dry Deposition of Long-Lived and Chemically Reactive Species over Heterogeneous Terrain. / Tetzlaff, G.; Dlugi, R.; Friedrich, K. et al.
In: Journal of atmospheric chemistry, Vol. 42, No. 1, 05.2002, p. 123-155.

Research output: Contribution to journal › Article › Research › peer review

Tetzlaff, G, Dlugi, R, Friedrich, K, Gross, G, Hinneburg, D, Pahl, U, Zelger, M & Mölders, N 2002, 'On Modeling Dry Deposition of Long-Lived and Chemically Reactive Species over Heterogeneous Terrain', Journal of atmospheric chemistry, vol. 42, no. 1, pp. 123-155. https://doi.org/10.1023/A:1015740203204

Tetzlaff, G., Dlugi, R., Friedrich, K., Gross, G., Hinneburg, D., Pahl, U., Zelger, M., & Mölders, N. (2002). On Modeling Dry Deposition of Long-Lived and Chemically Reactive Species over Heterogeneous Terrain. Journal of atmospheric chemistry, 42(1), 123-155. https://doi.org/10.1023/A:1015740203204

Tetzlaff G, Dlugi R, Friedrich K, Gross G, Hinneburg D, Pahl U et al. On Modeling Dry Deposition of Long-Lived and Chemically Reactive Species over Heterogeneous Terrain. Journal of atmospheric chemistry. 2002 May;42(1):123-155. doi: 10.1023/A:1015740203204

Tetzlaff, G. ; Dlugi, R. ; Friedrich, K. et al. / On Modeling Dry Deposition of Long-Lived and Chemically Reactive Species over Heterogeneous Terrain. In: Journal of atmospheric chemistry. 2002 ; Vol. 42, No. 1. pp. 123-155.

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abstract = "An explicit multi-layer subgrid-scheme was developed for a meso-γ/β-scale model to consider subgrid-scale surface heterogeneity, dry deposition, biogenic and anthropogenic emission of trace gases. Since dry deposition measurements of highly reactive trace species are scarce we try to evaluate this scheme by heuristic principles. The results of simulations conducted for a 5 × 5 km2 resolution with and without this scheme are evaluated by using results of a model run with 1 × 1 km2 resolution, which is taken as a 'grand thruth' and which has the same resolution as the subgrid. The explict multi-layer subgrid scheme provides a similar distribution of dry deposition fluxes as the much more computationally expensive simulation with the 1 × 1 km2 resolution. Dry deposition fluxes determined from observations give evidence that the explicit multi-layer subgrid scheme which does not require a constant flux approximation for a layer of several decameters leads to an improvement in determining the exchange between the atmosphere and the ground. Results of simulations with a microscale model show that the inhomogeneity at forest edges leads to an increase of the turbulent transports of up to a factor 4 compared to horizontally homogeneous terrain, which is assumed to be the conditions of the subgrid cells (and which is usually the assumption for the entire grid cell in mesoscale models). Inhomogeneity inside an extended stand of trees causes an overall increase of 5-10% with high local extremes, i.e. such an inhomogeneity results to an underestimation of dry deposition in meso-γ/β-scale models. The effects are most pronounced for a wind direction perpendicular to the forest edge.",

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Research@Leibniz University

On Modeling Dry Deposition of Long-Lived and Chemically Reactive Species over Heterogeneous Terrain

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