Author
Listed:
- Avinash N. Parde
(Frederick Research Center, Nicosia 1036, Cyprus)
- Kartik Koundal
(Indian Institute of Tropical Meteorology, Pune 411008, India)
- Utkarsh Bhautmage
(Department of Geography, National University of Singapore, Singapore 117570, Singapore)
- Michael Mau Fung Wong
(Division of Environment & Sustainability, Hong Kong University of Science and Technology, Hong Kong 999077, China)
- Christina Oikonomou
(Frederick Research Center, Nicosia 1036, Cyprus)
- Haris Haralambous
(Frederick Research Center, Nicosia 1036, Cyprus
Department of Electrical and Computer Engineering and Informatics, Frederick University, Nicosia 1036, Cyprus)
Abstract
The Eastern Mediterranean, notably Cyprus, is a climate change hotspot facing severe heatwaves. Accurate numerical weather prediction of these extremes requires precise land–atmosphere modeling and initial and boundary conditions. This study assesses replacing the default USGS Land-Use and Land-Cover (LULC) dataset with the 10 m ESA WorldCover 2021 dataset in the Weather Research and Forecasting (WRF) model to simulate the 15–29 July 2023 Cyprus heatwave. The updated LULC increased urban representation six-fold. Statistical validations showed significant improvements in 2 m temperature, relative humidity, and 10 m wind speed predictions across 85% of observational sites. Dynamically, it restored urban thermal memory, effectively capturing the daytime Urban Cool Island effect and nocturnal heat release. Furthermore, radiosonde validations showed that the update corrected nocturnal Planetary Boundary Layer Height (PBLH) underestimations and dampened exaggerated daytime convective mixing. However, crucial limitations remain. High-frequency diagnostics indicated the model still suffers from damped thermal inertia, missing the abrupt temperature spikes and rapid nocturnal cooling typical of semi-arid microclimates. Additionally, the updated configuration failed to capture severe atmospheric stagnation during peak heatwave conditions, highlighting that deep-rooted kinetic errors persist within default boundary layer parameterizations despite static surface improvements.
Suggested Citation
Avinash N. Parde & Kartik Koundal & Utkarsh Bhautmage & Michael Mau Fung Wong & Christina Oikonomou & Haris Haralambous, 2026.
"Role of High-Resolution Land Surface Representation in WRF Model for Forecasting Extreme Heatwave Conditions over Cyprus,"
Forecasting, MDPI, vol. 8(3), pages 1-23, May.
Handle:
RePEc:gam:jforec:v:8:y:2026:i:3:p:42-:d:1946107
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