An urban energy balance-guided machine learning approach for synthetic nocturnal surface urban heat island prediction: a heatwave event in Naples

Oliveira, Ana; Lopes, António; Niza, Samuel; Soares, Amílcar

doi:10.1016/j.scitotenv.2021.150130

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An urban energy balance-guided machine learning approach for synthetic nocturnal surface urban heat island prediction: a heatwave event in Naples
Citation	Oliveira A, Lopes A, Niza S, Soares A. Sci. Total Environ. 2021; 805: e150130.
Copyright	(Copyright © 2021, Elsevier Publishing)
DOI	10.1016/j.scitotenv.2021.150130
PMID	unavailable
Abstract	Southern European functional urban areas (FUAs) are increasingly subject to heatwave (HW) events, calling for anticipated climate adaptation measures. In the urban context, such adaptation strategies require a thorough understanding of the built-up response to the incoming solar radiation, i.e., the urban energy balance cycle and its implications for the Urban Heat Island (UHI) effect. Despite readily available, diurnal Land Surface Temperature (LST) data does not provide a meaningful picture of the UHI, in these midlatitudes FUAs. On the contrary, the mid-morning satellite overpass is characterized by the absence of a significant surface UHI (SUHI) signal, corresponding to the period of the day when the urban-rural air temperature difference is typically negative. Conversely, nocturnal high-resolution LST data is rarely available. In this study, an energy balance-based machine learning approach is explored, considering the Local Climate Zones (LCZ), to describe the daily cycle of the heat flux components and predict the nocturnal SUHI, during an HW event. While the urban and rural spatial outlines are not visible in the diurnal thermal image, they become apparent in the latent and storage heat flux maps - built-up infrastructures uptake heat during the day which is released back into the atmosphere, during the night, whereas vegetation land surfaces loose diurnal heat through evapotranspiration. For the LST prediction model, a random forest (RF) approach is implemented. RF results show that the model accurately predicts the LST, ensuring mean square errors inferior to 0.1 K. Both the latent and storage heat flux components, together with LCZ classification, are the most important explanatory variables for the nocturnal LST prediction, supporting the adoption of the energy balance approach. In future research, other locations and time-series data shall be trained and tested, providing an efficient local urban climate monitoring tool, where in-situ air temperature observations are not available. Language: en
Keywords	Heatwave; Land surface temperature; Local climate zones; Multisensor data fusion; Random forest; Satellite thermal imagery; Urban climate adaptation; Urban Heat Island