More frequent extreme rainfall events in a changing climate increase the risk of flash flooding. However, the flood hazard modelling required to reduce disaster risk in urban environments is often limited by the availability of data required for model calibration and validation. Here, we use a historical flood event captured by 5 m resolution satellite imagery to inform future flood hazard assessments in the West Bank, Palestine. Flooding in January 2013 affected over 12,500 people and large areas of agricultural land. Vegetation loss and damage were captured using a normalised difference vegetation index (NDVI), which was used as a reference flood extent. The physics-based HEC-RAS flood model best reproduced this NDVI-derived inundation extent (F1 score = 0.76), although the FastFlood model was able to produce a similar inundation pattern (F1 score = 0.74) over 300 times faster. Simulated flood depths from both models were similar. Climate analysis revealed that the January 2013 rainfall corresponded to a historical return period of between 1 in 5 and 1 in 10 years. In comparison, a 1 in 100-year rainfall event (RX1day (maximum 1-day precipitation) of 148 mm) based on historical data (1985–2014) could increase by almost 40 % (to 205 mm) in the mid-future (2041–2060), which could cause 23 % (4 km²) greater inundation compared to the 2013 event. Although the patterns of future precipitation in the region are uncertain, our flood hazard maps can support urban planning and infrastructure development to manage storm water runoff.

Title

International Journal of Disaster Risk Reduction

Publisher

ScienceDirect

Publisher Country

Netherlands

Indexing

Scopus

Impact Factor

4.5

Publication Type

Online only

Volume

132

Year

2025

Pages

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