The Differential Warming Response of Britain's Rivers (1982-2011)



Jonkers, Art RT and Sharkey, Kieran J ORCID: 0000-0002-7210-9246
(2016) The Differential Warming Response of Britain's Rivers (1982-2011). PLOS ONE, 11 (11). e0166247-.

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Abstract

River water temperature is a hydrological feature primarily controlled by topographical, meteorological, climatological, and anthropogenic factors. For Britain, the study of freshwater temperatures has focussed mainly on observations made in England and Wales; similar comprehensive data sets for Scotland are currently unavailable. Here we present a model for the whole of mainland Britain over three recent decades (1982-2011) that incorporates geographical extrapolation to Scotland. The model estimates daily mean freshwater temperature for every river segment and for any day in the studied period, based upon physico-geographical features, daily mean air and sea temperatures, and available freshwater temperature measurements. We also extrapolate the model temporally to predict future warming of Britain's rivers given current observed trends. Our results highlight the spatial and temporal diversity of British freshwater temperatures and warming rates. Over the studied period, Britain's rivers had a mean temperature of 9.84°C and experienced a mean warming of +0.22°C per decade, with lower rates for segments near lakes and in coastal regions. Model results indicate April as the fastest-warming month (+0.63°C per decade on average), and show that most rivers spend on average ever more days of the year at temperatures exceeding 10°C, a critical threshold for several fish pathogens. Our results also identify exceptional warming in parts of the Scottish Highlands (in April and September) and pervasive cooling episodes, in December throughout Britain and in July in the southwest of England (in Wales, Cornwall, Devon, and Dorset). This regional heterogeneity in rates of change has ramifications for current and future water quality, aquatic ecosystems, as well as for the spread of waterborne diseases.

Item Type: Article
Uncontrolled Keywords: Temperature, Seasons, Rivers, Models, Chemical, Climate Change, Global Warming, Water Quality, United Kingdom
Depositing User: Symplectic Admin
Date Deposited: 24 Mar 2017 15:55
Last Modified: 19 Jan 2023 07:08
DOI: 10.1371/journal.pone.0166247
Related URLs:
URI: https://livrepository.liverpool.ac.uk/id/eprint/3006628