Langjökull, energy balance and degree-day models station according to the 2004 SPOT5 images. Albedo below 0.1 has also been observed at glacier outlets of the nearby Vatnajökull ice cap (e. g. Lister, 1959; Rei- jmer et al., 1999; Guðmundsson et al., 2005), but is in that case mainly related to exposed volcanic tephra. At G1100, albedo declined gradually through the ab- lation seasons from 0.8–0.9 to 0.5–0.6, but jumped rapidly down to 0.4 when the previous year’s sum- mer surface was exposed around the middle of Au- gust 2001 and 2003 and the beginning of September 2004. Due to increased turbulent fluxes and reduced solar radiation, the relative contribution of net radi- ation decreased steadily throughout the summers in spite of the declining albedo. Frequent passage of low-pressure systems over Iceland results in Septem- ber being windier than the summer months of June to August. Highmelt rates were producedby eddy fluxes during the warm September months of 2001 and 2002 (Figure 3a-b). All the energy components supplied to the melting increased downglacier (Figure 5), the net long-wave radiation due to higher cloud cover and the net short- wave radiation as a result of lower albedo. Turbulent fluxes were maintained by down slope glacier winds and high air temperatures; wind directional constan- cies were 0.6 (in G500) and 0.5 (in G1100) where 0 means wind blowing equally from all directions and 1 wind solely down the steepest slope (e. g. Björnsson et al., 2005). The relative contribution of the net radia- tion components to melting was on average!60–70% in the ablation area (Figure 5b). The performance of degree-day models Daily melting was calculated with the degree-models (DDM1 and DDM2) at stakes and the two weather stations on the Hagafellsjökull outlet 2001–2005 (Fig- ure 1), using the ddf -parameters in Table 3. Although not describing the physicalmelt processes, the degree- day models simulated annual and seasonal variations in the ablation at G500 and G1100 reasonably (Figure 6). The most successful degree-day predictions were obtained by applying temperature observations away from the glacier (TS) using the constant wet adiabatic lapse rate ($), rather than temperatures observed on the glacier itself (TG). Lang (1968) concluded the same by investigating a small drainage basin of the Aletschgletscher glacier, Switzerland. This is shown in our data by correlations and residuals of both daily melting rates obtained with Eq. 5 (Table 4 and Figure 4c) and annual summer balance (Figure 6d-e). This Figure 5. Variation of weather pa- rameters, observed winter (bW ) and summer (bS) balances as well as the energy budget dur- ing days of melting (Mc # 0), along the profile in Figure 1. The values are averages over the en- tire ablation season 2004. ELA and GT: altitude of the equilib- rium line and the glacier ter- minus, respectively, in the year 2004. The lower x-axis in (b) shows the power supplied for melting and the upper the corre- sponding water equivalent units. – Veðurþættir og orkubúskapur í veðurstöðvum og mælistikum á og við jökulinn. JÖKULL No. 59 9

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