Abstract
Climate change implies changes in the frequency and magnitude of flood events. The influence of climate variability on flooding was evaluated by an analysis of sedimentary (palaeofloods) and documentary archives. A 500-year palaeoflood record at Montlleó River (657 km2 in catchment area), eastern Spain, revealed up to 31 palaeofloods with a range of discharges of 20–950 m3 s−1, and with at least five floods exceeding 740–950 m3 s−1. This information contrasts with the available gauged flood registers (since year 1971) with an annual maximum daily discharge of 129 m3 s−1. Our palaeoflood dataset indicates flood cluster episodes at (1) 1570–1620, (2) 1775–1795, (3) 1850–1890, and (4) 1920–1969. Flood rich periods 1 and 3 corresponded to cooler than usual (about 0.3 °C and 0.2 °C) climate oscillations, whereas 2 and 4 were characterised by higher inter-annual climatic variability (floods and droughts). This high inter-annual rainfall variability increased over the last 150 years, leading to a reduction of annual maximum flow. Flood quantiles (>50 years) calculated from palaeoflood+gauged data showed 30%–40% higher peak discharges than those using only instrumental records, whereas when increasing the catchment area (1500 km2) the discharge estimation variance decreased to ~15%. The results reflect the higher sensitivity of small catchments to changes on flood magnitude and frequency due to climate variability whereas a larger catchment buffers the response due to the limited extent of convective storms. Our findings show that extended flood records provide robust knowledge about hazardous flooding that can assist in the prioritization of low-regret actions for flood-risk adaptation to climate change.
Highlights
Global warming is leading to widespread changes in the hydrological cycle the chain linking greenhouse gases to outcome impacts is long and complex [1]
This paper presents recent advances in the use of palaeoflood data in order to improve our understanding of flood hazard changes under climate variability in small Mediterranean catchments
Chronological control of the timing of the main stratigraphic packages was acheived by combined radiocarbon and optically stimulated luminescence (OSL) ages, and supported by documentary flood records
Summary
Global warming is leading to widespread changes in the hydrological cycle the chain linking greenhouse gases to outcome impacts is long and complex [1]. A more variable climate and a more variable water cycle is likely to affect the pattern of rainfall-producing floods [2]. Widespread observations of changes in flood magnitude or frequency due to anthropogenic climate change are not widely available [1]. Three possible factors explain this increase in flood risk perception: higher population exposure, higher vulnerability, and higher frequency and/or intensity of hazard [4]. The specific weight of each of these factors included in the flood risk equation is still under debate
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