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  • 11. Traffc-maintenance_expenditures

    229 1 587 160 1970 18 591 42 413 2 166 86 101 - 892 5 131 2 310 201 - - - 157 805 1 652 904 1969 17 559 38 840 2 313 93 776 - 922 4 562 1 571 - - - - 159 543 1 832 354 1968 13 474 36 376 3 074 104 519 - 1 080 4 131 1 156 - - - - 163 811 1 964 368 1967 11 139 34 495 5 940 95 857 - 419 3 032 1 087 - - - - 151 968 1 936 249 1966 9 835 32 581 8 349 94 777 - 587 4 205 1 743 - - - - 152 077 2 032 936 /media/loftslag/Traffc-maintenance_expenditures.pdf
  • 12. The weather in Iceland in 2022

    was particularly cold; the temperature was 5 °C below average in both places. It hasn't been this cold in Reykjavík in December for over 100 year. Precipitation The year 2022 was unusually wet in Reykjavík. It was relatively wet in the capital in the beginning of the year, with March exceptionally wet. It was the wettest March on record, with total precipitation almost triple the average precipitation /about-imo/news/the-weather-in-iceland-in-2022
  • 13. The weather in Iceland in 2018

    of bright sunshine hours in June have not been as few since 1914. It was sunny in Reykjavík in March, August and September. In Akureyri the number of bright sunshine hours was above normal in March, June and September but below normal in April, July, August and October. Sea level pressure The annual average in Reykjavík was 1003.0 hPa, 2.9 below the 1961 to 1990 mean. The absolute /about-imo/news/the-weather-in-iceland-in-2018
  • 14. VI_2013_006

    lightning by the ATDnet system during (a) Grímsvötn 2004, (b) Eyjafjallajökull 2010 and (c) Grímsvötn 2011. A blue circle is at the vent location. 11 Figure 5. A map view, North (km) vs. East (km), of Grímsvötn 2011 lightning for the first 30 min (123 lightning), 1 hour (888), 3 hours (3340) and 24 hours (16041). The actual eruption site is marked with a black circle /media/vedurstofan/utgafa/skyrslur/2013/VI_2013_006.pdf
  • 15. 2005EO260001

    ) by fossil fuel burning and land-use change. As the terrestrial bio- sphere is an active player in the global carbon cycle, changes in land use feed back to the climate of the Earth through regulation of the content of atmospheric CO2, the most impor- tant greenhouse gas, and changing albedo (e.g., energy partitioning). Recently, the climate modeling community has started to develop more /media/jar/myndsafn/2005EO260001.pdf
  • 16. Paper-Olafur-Rognvaldsson_91

    the opportunity to model river runoff and glacier mass balance both in the current climate and also in a hypothetical future climate based on the CE /VO climate change scenarios. The climate of Iceland is largely governed by the interaction of orography and extra-tropical cyclones, both of which can be described quite accurately by present day atmospheric models. As a result, dynamical downscaling /media/ces/Paper-Olafur-Rognvaldsson_91.pdf
  • 17. Lorenzoni_Pidgeon_2006

    for people to conceptualise and to relate to their daily activities, arguably because it cannot be easily translated into the language of popular culture (Ungar, 2000; see also mental models of cli- mate change by Bostrom et al., 1994; Kempton, 1997; discussed later). Secondly, the various datasets available detailing public opinions and attitudes on climate PUBLIC VIEWS ON CLIMATE CHANGE: EUROPEAN /media/loftslag/Lorenzoni_Pidgeon_2006.pdf
  • 18. VI_2022_006_extreme

    77 91 109 Hraunaveita 132 116 136 159 117 140 169 Kvíslaveita 48 42 49 58 42 51 61 Sultartangi 66 57 68 80 58 69 84 Þingvallavatn 96 84 99 117 85 102 123 Þórisvatn 47 41 49 57 42 50 60 Tungnaá 76 67 79 92 67 80 98 Ufsarlón 104 92 108 126 93 112 134 36 Figure 19 – 1M5 maps for catchment Hálslón based on the ICRA dataset without projection (top left), with RCP 2.6 and 10th percentile /media/vedurstofan-utgafa-2022/VI_2022_006_extreme.pdf
  • 19. VI_2009_006_tt

    lake in a volcanic caldera in the interior of the Vatnajökull ice cap (Björns- son, 1988). Jökulhlaups from Grímsvötn have been known since at least the fourteenth century (Þórarinsson, 1939, 1974). In the beginning of the twentieth century there were about ten years between outbursts but the floods diminished with time and became more frequent. After a catastrophic, rapidly rising flood caused /media/vedurstofan/utgafa/skyrslur/2009/VI_2009_006_tt.pdf
  • 20. VI_2009_013

    to locate earthquakes in Iceland but the SIL-crustal model has no Moho boundary. Using this model in the routine, daily analysis, the majority of the earthquakes in Eyjafjallajökull form a 3-km-wide chimney between 1 and 10 km depth beneath the northern flank of the volcano. A smaller cloud is also visible between 19 and 25 km depth, about 1.5 km west of the main activity/cluster. 13 Figure 3 /media/vedurstofan/utgafa/skyrslur/2009/VI_2009_013.pdf

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