MODELING URBAN METEOROLOGY OVER IDEALISED CITIES. COMPARISON BETWEEN RESULTS OF URBAN PARAMETERIZATION IMPLEMENTED IN MESOSCALE MODEL AND HORIZONTAL SPATIAL AVERAGE PROPERTIES OBTAINED USING CFD SIMULATIONS
Item
Title (Dublin Core)
eng
MODELING URBAN METEOROLOGY OVER IDEALISED CITIES. COMPARISON BETWEEN RESULTS OF URBAN PARAMETERIZATION IMPLEMENTED IN MESOSCALE MODEL AND HORIZONTAL SPATIAL AVERAGE PROPERTIES OBTAINED USING CFD SIMULATIONS
Description (Dublin Core)
eng
Air quality inside the urban canopy layer (UCL) is important because here is where people live and a significant part of
the emissions are located. In this way, the modeling of UCL is also important. Different factors such as the increase of urban
population and the improvement of computational power, has produced an increasing interest on urban mesoscale modeling since
mid 1990s. However, the modeling of urban boundary layer is difficult because it is influenced by the complex morphology of a city
(buildings, cars, gardens) with different mechanical and thermal/radiative properties. In addition, the domain of mesoscale models
has a horizontal extension of several tens of kilometers (the whole city and its surrounding area) and, for computational reasons, it is
not possible to solve explicitly the flow around buildings. Therefore, urban parameterizations are necessary for high resolution
mesoscale simulations. On the other hand, Computational Fluid Dynamics (CFD) models can solve explicitly the flow around
buildings but their simulation domains cannot cover the whole city. In this work, focused on mechanical effects produced by
buildings, CFD simulations and the horizontal spatial average of the different flow properties are used to assess the performance of
an urban parameterization implemented on a mesoscale model and find its strengths and weaknesses. Horizontal spatial average of
the CFD results around the buildings are made in order to compare with similar mesoscale variables corresponding to a column of
computational cells over a urban zone with the same characteristics as the CFD configuration. In this case, the city is represented by
an array of cubes.
the emissions are located. In this way, the modeling of UCL is also important. Different factors such as the increase of urban
population and the improvement of computational power, has produced an increasing interest on urban mesoscale modeling since
mid 1990s. However, the modeling of urban boundary layer is difficult because it is influenced by the complex morphology of a city
(buildings, cars, gardens) with different mechanical and thermal/radiative properties. In addition, the domain of mesoscale models
has a horizontal extension of several tens of kilometers (the whole city and its surrounding area) and, for computational reasons, it is
not possible to solve explicitly the flow around buildings. Therefore, urban parameterizations are necessary for high resolution
mesoscale simulations. On the other hand, Computational Fluid Dynamics (CFD) models can solve explicitly the flow around
buildings but their simulation domains cannot cover the whole city. In this work, focused on mechanical effects produced by
buildings, CFD simulations and the horizontal spatial average of the different flow properties are used to assess the performance of
an urban parameterization implemented on a mesoscale model and find its strengths and weaknesses. Horizontal spatial average of
the CFD results around the buildings are made in order to compare with similar mesoscale variables corresponding to a column of
computational cells over a urban zone with the same characteristics as the CFD configuration. In this case, the city is represented by
an array of cubes.
Creator (Dublin Core)
Santiago, Jose Luis
Martilli, Alberto
Subject (Dublin Core)
eng
CFD Model;Mesoscale Model;Urban Canopy;Urban Parameterization
Publisher (Dublin Core)
Croatian meteorological society
Date (Dublin Core)
2008
Type (Dublin Core)
text
info:eu-repo/semantics/article
info:eu-repo/semantics/publishedVersion
Format (Dublin Core)
application/pdf
Identifier (Dublin Core)
https://hrcak.srce.hr/64272
eng
https://hrcak.srce.hr/file/96389
Source (Dublin Core)
Hrvatski meteorološki časopis
ISSN 1330-0083 (Print)
ISSN 1849-0700 (Online)
Volume 43
Issue 43/1
Language (Dublin Core)
eng
Rights (Dublin Core)
info:eu-repo/semantics/openAccess
The papers of this Journal are free of charge for personal or educational use, with respect of copyright of authors and publisher.