Please use this identifier to cite or link to this item: https://physrep.ff.bg.ac.rs/handle/123456789/1259
Title: Assessment of meteorological climate models as inputs for coastal studies
Authors: Bellafiore, Debora
Bucchignani, Edoardo
Gualdi, Silvio
Carniel, Sandro
Đurđević, Vladimir
Umgiesser, Georg
Keywords: Adriatic Sea;Climate change;Coastal processes;Meteorological forcing;Regional downscaling
Issue Date: 1-Apr-2012
Journal: Ocean Dynamics
Abstract: 
Modeling studies of future changes in coastal hydrodynamics, in terms of storm surges and wave climate, need appropriate wind and atmospheric forcings, a necessary requirement for the realistic reproduction of the statistics and the resolution of small scale features. This work compares meteorological results from different climate models in the Mediterranean area, with a focus on the Adriatic Sea, in order to assess their capability to reproduce coastal meteorological features and their possibility to be used as forcings for hydro-dynamic simulations. Five meteorological datasets are considered. They are obtained from two regional climate models, implemented with different spatial resolutions and setups and are downscaled from two different global climate models. Wind and atmospheric pressure fields are compared with measurements at four stations along the Italian Adriatic coast. The analysis is carried out both on simulations of the control period 1960-1990 and on the A1B Intergovernmental Panel for Climate Change scenario projections (2070- 2100), highlighting the ability of each model in reproducing the statistical coastal meteorological behavior and possible changes. The importance of simulated global- and regional-scale meteorological processes, in terms of correct spatial resolution of the phenomena, is also discussed. Within the Adriatic Sea, the meteorological climate is influenced by the local orography that controls the strengthening of north-eastern katabatic winds like Bora. Results show indeed that the increase in spatial resolution provides a more realistic wind forcing for the hydrodynamic simulations. Moreover, the chosen setup and the global climate models that drive the regional downscalings appear to play an important role in reproducing correct atmospheric pressure fields. The comparison between scenario and control simulations shows a small increase in the mean atmospheric pressure values, while a decrease in mean wind speed and in extreme wind events is observed, particularly for the datasets with higher spatial resolution. Finally, results suggest that an ensemble of downscaled climate models is likely to provide the most suitable climatic forcings (wind and atmospheric pressure fields) for coastal hydrodynamic modeling. © 2011 Springer Science+Business Media, LLC.
URI: https://physrep.ff.bg.ac.rs/handle/123456789/1259
ISSN: 1616-7341
DOI: 10.1007/s10236-011-0508-2
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