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Hydro‐climatic and land use changes in the River Lune catchment, North West England, implications for catchment management
Author(s) -
Orr H. G.,
Carling P. A.
Publication year - 2006
Publication title -
river research and applications
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.679
H-Index - 94
eISSN - 1535-1467
pISSN - 1535-1459
DOI - 10.1002/rra.908
Subject(s) - drainage basin , surface runoff , hydrology (agriculture) , environmental science , land cover , fluvial , land use , climate change , catchment hydrology , catchment area , vegetation (pathology) , physical geography , geology , geography , structural basin , ecology , oceanography , medicine , cartography , geotechnical engineering , pathology , biology , paleontology
Reported trends across the British Isles, illustrate changing rainfall gradients. Northern areas have become wetter in recent decades with greater variation between NW and SE rainfall totals. This paper explores hydro‐climatic changes in North‐West England over the last 140 years as part of a whole catchment investigation into the nature and causes of change in fluvial geomorphology. Variability in runoff in the Lune catchment is explained in terms of observed climate and land use changes; implications for river and catchment management are discussed. Area average annual rainfall in the North‐West of England show no clear trend over the last 100 years although rain gauges at higher altitudes appear to show increased totals. Over the last 30 years changes in the seasonality of rainfall have been observed. A greater proportion of annual rainfall has occurred in the winter half‐year and an increased frequency of wet‐days has been linked to catchment‐scale flooding. More rain falling on upland areas (> 300 m) has resulted in more rapid runoff from these areas enhanced by land use practices—specifically in heavily grazed hills with a short vegetation cover. The result is a highly varied runoff response within the catchment with localized increases in stream power and the potential for geomorphic change. This effect is ‘damped’ lower down the catchment highlighting the importance of within catchment variability and the need to conduct hydrological analysis at smaller than whole catchment scales. These findings have important implications for water resources, in particular: water storage within catchments; changes in the duration and frequency of floods and droughts; mobilization of sediment; erosion; channel and flood risk management; and ecological function. Copyright © 2006 John Wiley & Sons, Ltd.