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45 results were found for [77AGG. COM]m88 slot slot v89 slot 99 latar slot 999 slot sp777 slot v1u.


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  • 11. 2010_005_

    Century control runs, as well as 21st Century forecast runs, submitted by various institutions to the Intergovernmental Panel on Climate Change (IPCC) for their Forth 11 Table 1. General circulation and regional climate models that were considered in this study. Model Version Model Name, Institute BCCR BCM 2.0 Bergen Climate Model, Bjerknes Centre for Climate Research, Bergen, Norway CCCMA CGCM 3.1 /media/ces/2010_005_.pdf
  • 12. Dataseries and components

    -180 toxafen-26, -50, -62 BDE-47, -99, -100 Stórhöfði in the Westman Islands - foreign research: Continuous measurements of surface ozone. Ambient air: Instantaneous samples weekly using ~2 litre glass containers for atmospheric CO2, CH4, CO, H2, SF6 and N2O, as well as the C13 and O18 isotopes in carbondioxide and the C13 isotope in methane. For quality, a pair of identical samples are taken /pollution-and-radiation/pollution/components/
  • 13. bb100days_ens

    opportunity ever to follow a caldera subsidence in Iceland with modern scientific measurements and methods. Number of earthquakes between 16 August 2014 00:00 and 09 December 2014 at 08:30 all intrusion caldera Kistufell Askja HB / HBT TFJ Kverkfj. automatic ~ 34.000 - - - - - - - checked ~ 17.500 ~ 7.500 ~ 7.000 ~ 120 ~ 340 ~ 1500 ~ 470 ~20 M3.0-3.9 836 99 721 6 2 3 4 1 M4.0-4.9 462 7 453 1 1 /media/jar/bb100days_ens.pdf
  • 14. Dyrrdal_Anita_CES_2010

    parameters – In the light of climate change Norwegian Meteorological Institute met.no Observed changes in Norway between 1961-90 and 1979-08 • Winter precipitation has increased by 5-25 % • Winter temperature has increased by 0.91–1.34 ºC (Hanssen-Bauer et al., 2009) What about snow conditions? Introduction Data & Methods Results Norwegian Meteorological Institute met.no Snow parameters Start End /media/ces/Dyrrdal_Anita_CES_2010.pdf
  • 15. Flood from Skaftá

    eastern and western, are located in the western part of Vatnajökull Ice-cap. They form because of geothermal activity that melts the glacier from below and water accumulates beneath them. When the hydro static pressure is high enough for the water to lift the ice above and flow from below the cauldrons it causes a flood. Floods from the eastern-cauldron are usually larger than the floods /about-imo/news/flood-in-estern-skafta
  • 16. New article on glacier changes in

    to approx. 1890 and create a time series of the volume and mass changes of the glaciers that spans about 130 years.The results clearly show that the average mass loss of the Icelandic glaciers per unit area is among the highest of the main glacierized areas of the world, outside of Antarctica and Greenland. Such glaciers are now rapidly losing mass all over the Earth, causing rising sea level /about-imo/news/new-article-on-glacier-changes-in-iceland-over-the-past-130-years
  • 17. Flood from Skaftá

    eastern and western, are located in the western part of Vatnajökull Ice-cap. They form because of geothermal activity that melts the glacier from below and water accumulates beneath them. When the hydro static pressure is high enough for the water to lift the ice above and flow from below the cauldrons it causes a flood. Floods from the eastern-cauldron are usually larger than the floods /about-imo/news/flood-in-estern-skafta/
  • 18. VI_2020_008

    by the Peak-over-Threshold with MLE applied on daily and 24-hour accumulated precipitation from the ICRA. ............................... 58 8 Glossary 1M5 – Daily or 24-hour precipitation return level with a 5-year return period AMSAnnual Maxima Series CCCloseness Coefficient CDOClimate Data Operator EVA – Extreme Value Analysis GP – Generalized Pareto ICRA – Icelandic /media/vedurstofan-utgafa-2020/VI_2020_008.pdf
  • 19. Isskyrsla_20100407

    N66°44.92' W025°08.94' 79. N66°45.01' W025°08.50' 80. N66°46.32' W025°10.27' 81. N66°46.73' W025°07.19' 82. N66°46.01' W025°04.86' 83. N66°46.22' W025°04.33' 84. N66°47.12' W025°06.45' 85. N66°47.26' W025°04.36' 86. N66°48.44' W025°03.60' 87. N66°49.10' W025°04.45' 88. N66°51.68' W025°03.27' 89. N66°53.36' W024°59.25' 90. N66°55.39' W024°58.89' 91. N66°55.82' W024°58.13' 92. N66°56.15' W025°01.15 /media/hafis/skyrslur_lhg/Isskyrsla_20100407.pdf
  • 20. Water_resources_man_Veijalainen_etal

    range 90% 93.1593.29 93.2793.36 75.43–75.56 94.5994.71 2040–2069 range 90% 93.0993.31 93.2893.40 75.41–75.56 94.7294.83 2070–2099 range 90% 93.0293.32 93.2493.43 75.38–75.61 94.7994.91 Lowest water level (in the 30 year period) (m) Reference period 92.86 92.72 75.20 94.27 2010–2039 range 90% 92.6292.91 92.9693.13 75.24–75.33 94.4794.59 2040–2069 range 90% 92.5592.82 92.8893.12 75.19 /media/ces/Water_resources_man_Veijalainen_etal.pdf

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