After an international contest announced by the City of Abu Dhabi “Cool Abu Dhabi Challenge”1 and the article published as a digest of a paper titled A Nature-based Solution [1], the decision has been made to take part in improving thermal comfort in public spaces by mitigating the impact of the effect of Urban Heat Islands (UHI)2 in the city of the Belgrade. The basic research aims at achieving the balance between the conflicting impacts when the buildings with their infrastructure and water-green surrounding area are in such correlation that it fulfils acceptable living and heating standards and reduces the use of fossil fuels for cooling the urban areas (buildings). By implementing the remote detection it is possible to analyze and quantify the impact of over-building on the temperature rise in urban areas as well as the disturbance of the heating comfort and the increased demand for additional cooling. Now it is possible to create virtual models that will incorporate this newly-added urban vegetation into urban plans, depending on the evaporation potential that will affect the microclimate of the urban area. Such natural cooling can be measured and adapted and hence aimed at a potential decrease in areas with UHI emissions [2]. Suitable greenery in the summer season can be a useful improvement which concurrently enables and complements several cooling mechanisms—evaporative cooling and evapotranspiration, i.e. natural cooling systems. The remote detection shall establish and map the “healthy” and “unhealthy” greenery zones—that is the vegetation zones with the highest evaporative potential with the “cooling by evaporation” effect and also, by implementing the urban prediction model, it shall propose green infrastructure corridors aimed at a potential decrease in the Urban Heat Island Emission.
References
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Potić, I. (2019) Quantification of the Impact of High-Rise Buildings on Generating Heat Islands in the Area of the Realisation of The Special Purpose Plan “Belgrade Waterfront” in Belgrade. https://www.academia.edu/40981053/Quantification_of_the_Impact_of_High_rise_Buildings_on_Generating_Heat_ Islands_in_the_Area_of_the_Realisation_of_The_Special_Purpose_Plan_Belgrade_Waterfront_in_Belgrade
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Nguyen, D.V., Kuhnert, L. and Dieter Kuhnert, K. (2012) Spreading Algorithm for Efficient Vegetation Detection in Cluttered Outdoor Environments. Robotics and Autonomous Systems, 60, 1498-1507. https://doi.org/10.1016/j.robot.2012.07.022
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Pangestu, M. (2021) Green, Resilient, and Inclusive Development. A Nature-Based Solution. World Bank Group. https://naturebasedsolutions.org
