Sensitivity of Icelandic river basins to recent climate variations years and the sensitivity to precipitation variations by comparing wet and dry years, in a similar way as was done by Krasovskaia and Gottschalk (1992). The two- sided non-parametric Mann–Whitney test was used to assess the significance of a shift in the median of these variables, between warm and cold years and be- tween wet and dry years, except the flood occurrence rate (FOR) which was examined with a test based on the Poisson distribution described below. The Mann–Whitney test has been used in a similar con- text by Whitfield (2001) to examine temperature, pre- cipitation and discharge variations in Canada. For the Mann–Whitney test, pre-whitening was undertaken to remove serial correlation, as recommended by Yue and Wang (2002): Yt = Xt − r1Xt−1 (2) where r1 is the serial correlation coefficient for a time lag of 1 year, Xt is the original time series and Yt the pre-whitened series. After pre-whitening, the se- ries is expected to be uncorrelated, i.e. a white noise. The pre-whitened series were only used for the Mann– Whitney test whereas results regarding the sign and magnitude of changes between subsets were calcu- lated from the original series without pre-whitening. The change in flood occurrence rate between warm and cold years and then between wet and dry years was evaluated by comparing their ratio, θ, as- suming that the flood process can be described by a Poisson distribution. This comparison was performed by testing the null hypothesis H0 : θ = 1 against H1 : θ 6= 1. The R-package rateratio.test (Fay, 2009) was used. The test is based on conditioning the sum of two independent Poisson random variables X and Y as follows: Y |X + Y = Z ∼ Binomial(Z, p(θ)) (3) where X ∼Poisson(nxλx), Y ∼Poisson(nyλy), λx is the average flood occurrence rate per year of X , λy is the average flood occurrence rate per year of Y , nx and ny the number of years in each sample, θ = λy/λx, and p(θ) = nyλy nyλy + nxλx = nyθ nyθ + nx (4) The 100(1-α)% confidence interval for θ is then de- rived from the 100(1-α)% confidence interval for p(θ). RESULTS The hydrological response to temperature and precip- itation variations was examined by calculating differ- ences in the hydrological variables between warm and cold years and wet and dry years respectively. Ta- ble 3 presents the temperature, precipitation and dis- charge statistics for each subset within the 1971–2006 period and Tables 4 and 5 present the derived differ- ences. The change in the median timing is given in days, whereas the change in the median of all vari- ables describing a magnitude is given in % of the me- dian in cold and dry years, respectively. Only changes for which the p-value < 0.1 were considered signifi- cant. Maps showing the results of the statistical tests are presented in Figures 3–4. Annual temperature and precipitation differences Depending on catchment, the median annual temper- ature in warm years was 1.1–1.4 ◦C warmer than in cold years. This difference was significant at the 5% level for all catchments. The corresponding me- dian annual precipitation was not significantly dif- ferent between warm and cold years, except for the southern basins VHM-64 (p < 0.1) and VHM-96 (p < 0.05) where warm years were slightly wetter than cold years, and for the basin VHM-144 (p < 0.05) north of Hofsjökull glacier, for which warm years brought slightly less precipitation than cold years. The median annual precipitation in wet years was 40–58% larger than in dry years and this difference was significant at the 5% level for all catchments. The corresponding median annual temperature was not significantly dif- ferent between wet and dry years except in the south, at catchment VHM-96 (p < 0.1), where wet years were warmer than dry years, and in the northeast, at catch- ment VHM-26 (p < 0.1), where wet years were colder than dry years. Hydrological response to temperature variations The hydrological response to temperature variations was examined by testing the significance of differ- ences in the median or mean of each annual hydrolog- JÖKULL No. 63, 2013 77

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