Abstract
Floods are the most common and widely distributed natural hazard, threatening life and property worldwide. Governments worldwide are facing significant challenges associated with flood hazard, specifically: increasing urbanization; against the background of uncertainty associated with increasing climate variability under climate change. Thus, flood hazard assessments need to consider climate change uncertainties explicitly. This paper explores the role of climate change uncertainty through uncertainty analysis in flood modelling through a probabilistic framework using a Monte Carlo approach and is demonstrated for case study catchment. Different input, structure and parameter uncertainties were investigated to understand how important the role of a non-stationary climate may be on future extreme flood events. Results suggest that inflow uncertainties are the most influential in order to capture the range of uncertainty in inundation extent, more important than hydraulic model parameter uncertainty, and thus, the influence of non-stationarity of climate on inundation extent is critical to capture. Topographic controls are shown to create tipping points in the inundation–flow relationship, and these may be useful and important to quantify for future planning and policy. Full Monte Carlo analysis within the probabilistic framework is computationally expensive, and there is a need to explore more time-efficient strategies which may result in a similar estimate of the full uncertainty. Simple uncertainty quantification techniques such as Latin hypercube sampling approaches were tested to reduce computational burden.
Highlights
Floods are the most common and widely distributed natural hazard, threatening life and property worldwide (Jonkman and Vrijling 2008)
It can be inferred that the relative scale of input hydrograph uncertainty to hydraulic model parameter uncertainty (CMU and EVDU > Hydraulic model parameter uncertainty (HMPU)) is transferable between sites
This study has explicitly captured the uncertainty associated with climate model parameterization and the flood modelling process using a probabilistic framework and investigated the influence of climate change projections on future flood hazard predictions
Summary
Floods are the most common and widely distributed natural hazard, threatening life and property worldwide (Jonkman and Vrijling 2008). Flood hazards result from many different sources (e.g. coastal, fluvial, pluvial or estuarine), whilst the consequences arise from the adverse impacts of flooding on people, property, human health, the environment, cultural heritage and economic activity (Beevers et al 2016). The UN estimates that 1 Bn people live in areas of potential flood risk and damage caused by floods on a global scale has been significant in recent decades (Jonkman and Vrijling 2008). In the last decade (2007–2017), there have been around 200 significant flood events in Europe, resulting in almost 1000 deaths, affecting 3.9 M people and causing over $55 Bn worth of damage (2018). Looking forward, governments worldwide are facing significant challenges associated with flood risk, : increasing urbanization; the current drive to control public expenditure; and the background of uncertainty associated with increasing climate variability under climate change (Guerreiro et al 2018)
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