Advances in Science and Research www.adv-sci-res.net 1992-0628 1992-0636 3 8th EMS Annual Meeting and 7th European Conference on Applied Climatology 2008 2009 10.5194/asr-3-5-2009 http://www.adv-sci-res.net/3/5/2009/ http://www.adv-sci-res.net/3/5/2009/asr-3-5-2009.html http://www.adv-sci-res.net/3/5/2009/asr-3-5-2009.pdf 5 7 2009-04-01 Spatial and temporal variability of ozone deposition Cs. Czender E. Komjáthy R. Mészáros mrobi@nimbus.elte.hu I. Lagzi Hungarian Defence Forces, Geoinformation Service, Budapest, Hungary Department of Meteorology, Eötvös Loránd University, Budapest, Hungary Soil moisture and ozone deposition velocity under continental climate conditions were estimated using a newly developed algorithm. The relationship between soil moisture and deposition velocity was investigated and analysed. These results emphasize the importance of a sophisticated parameterization of soil moisture in surface-atmosphere interaction processes. Ács, F.: On the relationship between the spatial variability of soil properties and transpiration, Idöjárás, 107, 257–272, 2003. Chen, F. and Dudhia, J.: Coupling an Advanced Land Surface-Hydrology Model with the Penn State-NCAR MM5 Modeling System. Part I: Model Implementation and Sensitivity, Mon. Weather Rev., 129, 569–585, 2001. Lagzi, I., Mészáros, R., Horváth, L., Tomlin, A., Weidinger, T., Turányi, T., Ács, F., and Haszpra, L.: Modelling ozone fluxes over Hungary, Atmos. Environ., 38, 6211–6222, 2004. Lagzi, I., Mészáros, R., Ács, F., Tomlin, A. S., Haszpra, L., and Turányi, T.: Description and evaluation of a coupled Eulerian transport-exchange model. Part I: Model development, Idöjárás, 110, 349–363, 2006. Mészáros, R., Lagzi, I., Juhász, Á., Szinyei, D., Vincze, Cs., Horányi, A., Kullmann, L., and Tomlin, A. S.: Description and evaluation of a coupled Eulerian transport-exchange model. Part II: Sensitivity analysis and application, Idöjárás, 110, 365–377, 2006. Mészáros, R., Zsély, I. Gy., Szinyei, D., Vincze, Cs., and Lagzi, I.: Sensitivity analysis of an ozone deposition model, Atmos. Environ., 43, 663–672, 2009a. Mészáros, R., Szinyei, D., Vincze, Cs., Lagzi, I., Turányi, T., Haszpra, L., and Tomlin, A. S.: Effects of the soil wetness state on the stomatal ozone fluxes over Hungary, Int. J. Environ Pollut., 36, No 1/2/3, 180–194, 2009b. Mintz, Y. and Walker, G. K.: Global fields of soil moisture and land surface evapotranspiration derived from observed precipitation and surface air temperature, J. Appl. Meteorol., 32, 1305–1334, 1993. Musselman, R. C., Lefohn, A. S., Massman, W. J., and Heath, R. L.: A critical review and analysis of the use of exposure- and flux-based ozone indices for predicting vegetation effects, Atmos. Environ., 40, 1869–1888, 2006. Paoletti, E. and Manning, W. J.: Toward a biologically significant and usable standard for ozone that will also protect plants, Environ. Pollut., 150, 85–95, 2007.