Guðmundsson et al. G500 and G1100, respectively, which is well within the errors of !35 W m"2 of Mc and 40 W m"2 of Mm, calculated by using the instrument errors given in Table 1. Empirical ablation models Two degree-day models were used to relate the spe- cific ablation rate (as in m d"1 w. eq.) at an elevation hG on the glacier to degree-days, either as observed on the glacier (DDM1, Eq. 9) or estimated at a base station outside the glacier (DDM2, Eq. 10): as = ddf1 t2& t1 T +G (9) as = ddf2 t2& t1 ! TS " $(hG " hS) "+ . (10) The sums are computed over the period from day t 1 to t2 of the ablation season, ddf1 and ddf2 are degree- day factors that remain constant with time but are dif- ferent for snow and ice/firn. The number of degree- days calculated for each day is the mean daily tem- perature above the melting point, 0 !C, + stands for degree-days over a threshold of 0 !C, TG is the ob- served temperature 2 m above the surface at elevation hG on the glacier, TS is the observed temperature at a weather station of elevation hS away from the glacier (here S475) and the constant $ = 0.6%10"2 !Cm"1 approximates the adiabatic lapse rate. The tempera- ture TG is damped by energy exchange processes near the melting ice surface but (TS " $(hG " hS)) is typ- ically representative for the atmosphere temperature at an elevation hG above the off-glacier weather sta- tion S474, and not influenced by a melting ice surface. Hence, (TS " $(hG " hS)) is not an estimate of the damped boundary layer temperature TG, but rather an estimate of the temperature at height hG in the free atmosphere surrounding the glacier. The ddf -parameters of DDM1 and DDM2 (Table 3) were scaled to fit the water equivalent of the daily energy supplied for melting (Eq. 5), using: a) a com- bined 2001–2005 energy budget calculations at the two AWSs (G500 and G1100), and b) the 2004 energy budget at three mass balance stakes at 700 to 1000 m a. s. l. (Figure 1), inferred by assuming the parame- ters TG, e, u, Qi and Ii of Eqs. (4–7) to vary linearly with elevation between the observation sites G500 and G1100, and setting Io equal to 315Wm"2 (for a melt- ing surface) and Qo = Qi · " with albedo (") esti- mated by combining information from the stake ob- served winter balance (bW ; for snow/ice transition), the observed daily albedo at the two AWS sites and three optical SPOT5 satellite images (5x5 m spatial resolution) acquired on August 12, 17 and 19, 2004. When fitting the ddf -parameters, the energy bal- ance data-sets were divided into periods with melting of snow and ice/firn, respectively. The timing for the exposure of ice/firn was estimated when an abrupt re- duction in albedo took place as the summer surface of the previous year was exposed, as well as consider- ing the melting needed to remove the measured winter accumulation (bW ). Albedo changes due to new snow that was deposited on an ice/firn surface and melted was also easily detected from the albedo profiles. The uncertainty of the ddf -parameters was estimated at G1100 and G500 (Table 3) as one standard deviation of the annual variance of ddf -parameters fitted sepa- rately to each year. RESULTS Energy budget during the ablation seasons 2001 to 2005 The ablation seasons under investigation started at the end of April/beginning of May and terminated in September/early October. Net radiation was typically the main contributor to the total energy supplied for melting during the months of June through August but was equalled or surpassed by turbulent fluxes during occasional spells of high temperatures and strong winds (Figure 3a-b). Throughout the ablation seasons, the albedo and the global radiation were the main factors determining the net radiation (Figures 3c-d) as the long-wave net radi- ation was fairly constant; slightly negative, with radia- tion emitted from the melting glacier hovering around 315 W m"2 (Figure 3c). Daily variations in the en- ergy budget were, however, generally highly related to turbulent eddy fluxes (Table 4), especially during the 6 JÖKULL No. 59

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