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A sensitivity analysis of lake water level response to changes in climate and river regimes |
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| Institution: | Water Resources and Environmental Engineering Research Group, Faculty of Engineering, University of Oulu, PO Box 4300, FIN-90014 Oulu, Finland |
| Abstract: | Lake water level regimes are influenced by climate, hydrology and land use. Intensive land use has led to a decline in lake levels in many regions, with direct impacts on lake hydrology, ecology and ecosystem services. This study examined the role of climate and river flow regime in controlling lake regimes using three different lakes with different hydraulic characteristics (volume-inflow ratio, CIR). The regime changes in the lakes were determined for five different river inflows and five different climate patterns (hot-arid, tropical, moderate, cold-arid, cold-wet), giving 75 different combinations of governing factors in lake hydrology. The input data were scaled to unify them for lake comparisons. By considering the historical lake volume fluctuations, the duration (number of months) of lake volume in different ‘wetness’ regimes from ‘dry’ to ‘wet’ was used to develop a new index for lake regime characterisation, ‘Degree of Lake Wetness’ (DLW). DLW is presented as two indices: DLW1, providing a measure of lake filling percentage based on observed values and lake geometry, and DLW2, providing an index for lake regimes based on historical fluctuation patterns. These indices were used to classify lake types based on their historical time series for variable climate and river inflow. The lake response time to changes in hydrology or climate was evaluated. Both DLW1 and DLW2 were sensitive to climate and hydrological changes. The results showed that lake level in high CIR systems depends on climate, whereas in systems with low CIR it depends more on river regime. |
| Keywords: | Lake hydrology Lake water level River regime Climate Water balance CIR"} {"#name":"keyword" "$":{"id":"kw0035"} "$$":[{"#name":"text" "_":"capacity inflow ratio SDSD"} {"#name":"keyword" "$":{"id":"kw0045"} "$$":[{"#name":"text" "_":"standard deviation of scaled data P-E"} {"#name":"keyword" "$":{"id":"kw0055"} "$$":[{"#name":"text" "_":"effective precipitation MLC"} {"#name":"keyword" "$":{"id":"kw0065"} "$$":[{"#name":"text" "_":"maximum lake capacity or volume MAF"} {"#name":"keyword" "$":{"id":"kw0075"} "$$":[{"#name":"text" "_":"mean annual river flow DLW"} {"#name":"keyword" "$":{"id":"kw0085"} "$$":[{"#name":"text" "_":"degree of lake wetness NSP"} {"#name":"keyword" "$":{"id":"kw0095"} "$$":[{"#name":"text" "_":"number of months in which outflow from lake occurred A Ma"} {"#name":"keyword" "$":{"id":"kw0105"} "$$":[{"#name":"text" "_":"absolute maximum lake volume during 40-year simulation A Mi"} {"#name":"keyword" "$":{"id":"kw0115"} "$$":[{"#name":"text" "_":"absolute minimum lake volume during 40-year simulation MMR"} {"#name":"keyword" "$":{"id":"kw0125"} "$$":[{"#name":"text" "_":"maximum–minimum volume ratio AMR"} {"#name":"keyword" "$":{"id":"kw0135"} "$$":[{"#name":"text" "_":"absolutemaximum–minimum volume ratio Bwh"} {"#name":"keyword" "$":{"id":"kw0145"} "$$":[{"#name":"text" "_":"hot-arid desert climate according to the Köppen climate classification Cs"} {"#name":"keyword" "$":{"id":"kw0155"} "$$":[{"#name":"text" "_":"temperate with hot dry summer climate according to the Köppen climate classification Aw"} {"#name":"keyword" "$":{"id":"kw0165"} "$$":[{"#name":"text" "_":"tropical savannah climate according to the Köppen climate classification Bsk"} {"#name":"keyword" "$":{"id":"kw0175"} "$$":[{"#name":"text" "_":"cold arid steppe climate according to the Köppen climate classification Dfc"} {"#name":"keyword" "$":{"id":"kw0185"} "$$":[{"#name":"text" "_":"cold without dry season climate according to the Köppen climate classification |
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