Influence of the Local Urban Environment on the Thermoradiative and Hydrological Behavior of a Garden Lawn

Abstract Several urban canopy models now incorporate urban vegetation to represent local urban cooling related to natural soil and plant evapotranspiration. Nevertheless, little is known about the realism of simulating these processes and turbulent exchanges within the urban canopy. Here, the couple...

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Published inJournal of applied meteorology and climatology Vol. 61; no. 1; pp. 25 - 42
Main Authors Lemonsu, Aude, Munck, Cécile de, Redon, Emilie, Masson, Valéry, Keravec, Pascal, Rodriguez, Fabrice, Pineau, Laetitia, Legain, Dominique
Format Journal Article
LanguageEnglish
Published Boston American Meteorological Society 01.01.2022
Subjects
Atmospheric and Oceanic Physics
Atmospheric models
Canopies
Canopy
Earth Sciences
Energy
Energy balance
Evapotranspiration
Heat
Heterogeneity
Humidity
Hydrology
Influence
Leaves
Meteorology
Modelling
Moisture content
Parameterization
Physics
Physiology
Plant cover
Radiation
Roughness
Sciences of the Universe
Simulation
Soil
Soil characteristics
Soil properties
Soil temperature
Soil water
Urban areas
Urban environments
Vegetation
Water content
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Summary:Abstract Several urban canopy models now incorporate urban vegetation to represent local urban cooling related to natural soil and plant evapotranspiration. Nevertheless, little is known about the realism of simulating these processes and turbulent exchanges within the urban canopy. Here, the coupled modeling of thermal and hydrological exchanges was investigated for a lawn located in an urban environment and for which soil temperature and water content measurements were available. The ISBA diffusive (ISBA-DF) surface–vegetation–atmosphere transfer model is inline coupled to the Town Energy Balance urban canopy model to model mixed urban environments. For the present case study, ISBA-DF was applied to the lawn and first evaluated in its default configuration. Particular attention was then paid to the parameterization of turbulent exchanges above the lawn and to the description of soil characteristics. The results highlighted the importance of taking into account local roughness related to surrounding obstacles for computing the turbulent exchanges over the lawn and simulating realistic surface and soil temperatures. The soil nature and texture vertical heterogeneity are also key properties for simulating the soil water content evolution and water exchanges.
ISSN:1558-8424
1558-8432
DOI:10.1175/JAMC-D-21-0067.1