Abstract
AbstractIn the summer of 1976, north‐west Europe experienced an exceptional heatwave and drought, which impacted agriculture and public water supply. This study aims to assess how the likelihood of the event in the present‐day climate has changed since 1976 because of climate change. The analysis focuses on the England and Wales region, which was particularly badly impacted. Three key factors contributing to the extreme summer were identified: the dry preceding winter–spring period, the dry summer and the hot summer. Following the principles of event attribution, three methods are used to evaluate the change in event risk: one using observational data, a second using CMIP5 coupled climate models and a third using HadGEM3‐A atmosphere‐only simulations. This is the first time that this method has been used to evaluate how the risk of a historical extreme event has changed since it originally occurred. The results from the three methods agree qualitatively. The probability of a summer at least as hot as 1976 has increased significantly between the 1970s and the present‐day climate (estimated risk ratios 11 (5–95% confidence interval (CI) [7,14]), 9 (CI [4,28]) and 19 (CI [5,25]) based on the three respective methods). In contrast, no significant change in the probability of an extreme dry winter–spring or an extreme dry summer was found. However, the joint probability of an extreme dry winter–spring followed by an extreme hot summer and the probability of an extreme hot and dry summer have both increased significantly between the 1970s and the present day (estimated risk ratios between 5 and 79, and between 3 and 39, respectively). Water resource systems should therefore be robust enough to cope with more frequent occurrences of summers as extreme as 1976.
Highlights
Summer heatwaves and prolonged periods of low rainfall leading to drought have serious implications for many sectors, including water resource management, agriculture and human health
6.1 Summary of results used to achieve this: one based on observations, a second based on coupled climate model simulations (CMIP5) and a third based on atmosphere-only climate model simulations (HadGEM3-A)
The methodologies followed the principles of event attribution to assess the probability of the extreme events occurring in the different climates
Summary
Summer heatwaves and prolonged periods of low rainfall leading to drought have serious implications for many sectors, including water resource management, agriculture and human health. The exceptionally dry winter of 1975/1976 meant that reservoirs, lakes and aquifers, which form the basis of the UK’s water supply system, did not recharge as they normally do over the winter period This led to reductions in available water for agriculture, industry and public water supply (Murray, 1977). The reduction in water availability resulted in severe restrictions on water usage This had significant impacts on the agricultural sector, which saw a large reduction in productivity; industry, which was forced to reuse water; and the public, with widespread hosepipe bans, standpipes and in some places the public water supply being turned off entirely for parts of the day or night (Rodda and Marsh, 2011; Taylor et al, 2009)
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