P. Crochet Glaciers cover almost 11% of the area of Ice- land. More than 75% of the electricity production comes from hydropower and the largest hydroelec- tric power stations are fed by glacial rivers (e.g. Thor- steinsson and Björnsson, 2011). Projected increase in surface air temperature in coming decades is ex- pected to deplete snow storage, reduce the volume of Icelandic ice-caps and have an impact on stream- flow volumes and seasonality in glacial and non- glacial rivers (Jóhannesson 1997; Aðalgeirsdóttir et al., 2006; Jóhannesson et al., 2007; Björnsson and Pálsson, 2008; Jónsdóttir, 2008; Guðmundsson et al., 2009; Einarsson and Jónsson, 2010; Thorsteinsson and Björnsson, 2011). If realised, this development would have a profound effect on water resources and major implications for the design, management and operation of reservoirs used to store water for hy- dropower production and other uses. Large uncertainties remain about future changes of climate and their effects on hydrology. An exam- ination of the hydrological response to observed cli- mate variations improves our understanding of the re- sponse of hydrological systems to climate forcing and thereby improves our ability to assess the hydrolog- ical impact of future climate changes. Here, the hy- drological response of different types of catchments in Iceland to past variations in temperature and pre- cipitation is analysed considering a large collection of variables describing various aspects of the hydrologi- cal cycle. DATA AND METHODS Data Eight watersheds, for which daily flow discharge mea- surements are available for at least thirty years, were selected for this study. They are relatively unaltered by human influences such as regulation, drainage and land-use (Figure 1 and Table 1). Rivers in Iceland are frequently classified according to their source (Rist, 1990; Jónsdóttir et al., 2008; Jónsdóttir and Uvo, 2009): direct runoff (D), groundwater fed (L), glacial (J) and whether they flow through lakes (S). Direct runoff rivers are characterized by rather constant low winter flow, when precipitation is stored in the snow- pack, high flow in spring with snowmelt, low summer flow and a secondary peak in autumn due to rainfall. Glacial rivers display a similar hydrograph in winter but high discharge is observed from spring to autumn due to both snow melt in spring and glacier melt in summer. Groundwater fed rivers are characterized by fairly constant discharge during the year. The studied river catchments are of mixed origin ( Table 1), three of them are non-glacierized and five partly glacier- ized, two of which receive a large groundwater contri- bution to their flow (VHM-64 and VHM-66). Figure 2 presents the annual streamflow hydrographs, nor- malized by the annual mean daily flow, for the period 1971–2000. In order to describe and quantify climatic varia- tions in the past decades and their effect on hydrology, 1-km gridded daily temperature (Crochet and Jóhann- esson, 2011) and daily precipitation series (Crochet et al., 2007; Jóhannesson et al., 2007) were used. The temperature data set was obtained by gridding tem- perature observations at meteorological stations with a spline interpolation after elevation correction, us- ing a fixed lapse rate of 6.5 ◦C/km. The precipitation data set was obtained by dynamical downscaling of ERA-40 precipitation (Uppala et al., 2005) with an orographic precipitation model (Smith and Barstad, 2004) whose parameters were optimized to best sim- ulate precipitation observations at meteorological sta- tions and winter balance measurements on three large glaciers. Hydrological variables A total of 22 variables were defined to analyse various aspects of the hydrological response to climatic varia- tions (Table 2). A hydrological year from Sept. 1st to Aug. 31st was used in all cases. The role of snow stor- age and snow and glacier meltwater runoff on stream- flow variations was evaluated from the gridded daily precipitation and temperature series. Daily precipi- tation was split into rain and snow water equivalent (SWE) with a fixed temperature threshold of 1 ◦C, commonly used in glaciological studies in Iceland (Jóhannesson et al., 1995; Jóhannesson, 1997; Aðal- geirsdóttir et al., 2006; Guðmundsson et al., 2009). Snowpack (accumulated SWE) and meltwater runoff were estimated daily at each grid point, using a simple 72 JÖKULL No. 63, 2013

Qupperneq 1
Qupperneq 2
Qupperneq 3
Qupperneq 4
Qupperneq 5
Qupperneq 6
Qupperneq 7
Qupperneq 8
Qupperneq 9
Qupperneq 10
Qupperneq 11
Qupperneq 12
Qupperneq 13
Qupperneq 14
Qupperneq 15
Qupperneq 16
Qupperneq 17
Qupperneq 18
Qupperneq 19
Qupperneq 20
Qupperneq 21
Qupperneq 22
Qupperneq 23
Qupperneq 24
Qupperneq 25
Qupperneq 26
Qupperneq 27
Qupperneq 28
Qupperneq 29
Qupperneq 30
Qupperneq 31
Qupperneq 32
Qupperneq 33
Qupperneq 34
Qupperneq 35
Qupperneq 36
Qupperneq 37
Qupperneq 38
Qupperneq 39
Qupperneq 40
Qupperneq 41
Qupperneq 42
Qupperneq 43
Qupperneq 44
Qupperneq 45
Qupperneq 46
Qupperneq 47
Qupperneq 48
Qupperneq 49
Qupperneq 50
Qupperneq 51
Qupperneq 52
Qupperneq 53
Qupperneq 54
Qupperneq 55
Qupperneq 56
Qupperneq 57
Qupperneq 58
Qupperneq 59
Qupperneq 60
Qupperneq 61
Qupperneq 62
Qupperneq 63
Qupperneq 64
Qupperneq 65
Qupperneq 66
Qupperneq 67
Qupperneq 68
Qupperneq 69
Qupperneq 70
Qupperneq 71
Qupperneq 72
Qupperneq 73
Qupperneq 74
Qupperneq 75
Qupperneq 76
Qupperneq 77
Qupperneq 78
Qupperneq 79
Qupperneq 80
Qupperneq 81
Qupperneq 82
Qupperneq 83
Qupperneq 84
Qupperneq 85
Qupperneq 86
Qupperneq 87
Qupperneq 88
Qupperneq 89
Qupperneq 90
Qupperneq 91
Qupperneq 92
Qupperneq 93
Qupperneq 94
Qupperneq 95
Qupperneq 96
Qupperneq 97
Qupperneq 98
Qupperneq 99
Qupperneq 100
Qupperneq 101
Qupperneq 102
Qupperneq 103
Qupperneq 104
Qupperneq 105
Qupperneq 106
Qupperneq 107
Qupperneq 108
Qupperneq 109
Qupperneq 110
Qupperneq 111
Qupperneq 112
Qupperneq 113
Qupperneq 114
Qupperneq 115
Qupperneq 116
Qupperneq 117
Qupperneq 118
Qupperneq 119
Qupperneq 120
Qupperneq 121
Qupperneq 122
Qupperneq 123
Qupperneq 124
Qupperneq 125
Qupperneq 126
Qupperneq 127
Qupperneq 128
Qupperneq 129
Qupperneq 130
Qupperneq 131
Qupperneq 132
Qupperneq 133
Qupperneq 134
Qupperneq 135
Qupperneq 136
Qupperneq 137
Qupperneq 138
Qupperneq 139
Qupperneq 140
Qupperneq 141
Qupperneq 142
Qupperneq 143
Qupperneq 144
Qupperneq 145
Qupperneq 146
Qupperneq 147
Qupperneq 148
Qupperneq 149
Qupperneq 150
Qupperneq 151
Qupperneq 152