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  • 11. Sigurður Th. Rögnvaldsson

    and beyond year 2000. Phys. Earth Planet. Inter. 113, 89 101. Roberts, R. G., A. Lindfors, A. Christoffersson, Reynir Böðvarsson og Sigurður Th. Rögnvaldsson 1993. Three-component data as an aid to seismic event detection and asociation: A case study using data from the SIL (Iceland) network. Computers and Geosciences 19, pp. 123 134. Slunga, R., Sigurður Th. Rögnvaldsson og Reynir Böðvarsson /earthquakes-and-volcanism/conferences/jsr-2009/sigurdur
  • 12. glacier_mass_balance_poster

    - accuracy on cm scale at gentle sloping terrain - higher errors at rough and steep sloping terrain - often false values due to frequent occurence of clouds in the area c) GPS profiles and points observed at ice free areas - accuracy ~1 m in elevation Characteristics Ice cap E: Eyjafjallajökull To: Torfajökull Ti: Tindfjallajökull Area (km2) Range in elevation (m a.s.l.) 81 15 14 180-1630 660-1480 /media/ces/glacier_mass_balance_poster.pdf
  • 13. Kok_1-scenarios-lecture-1

    of complex interdependencies, the effort to solve one aspect may create other problems. Complex problem: A problem with many relationships between parts that give rise to collective behaviour of the system. Complex system approach A broad term encompassing a research approach to problems in many diverse disciplines including computer science, AI, biology, sociology, etc. Common elements /media/loftslag/Kok_1-scenarios-lecture-1.pdf
  • 14. 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
  • 15. Gudmundsson-etal-2011-PR-7282-26519-1-PB

    are currently melting at a fast rate. Over recent decades, annual mass balance field observations on the three largest ice caps in Iceland* Langjo¨kull (ca. 900 km2), Hofsjo¨kull (ca. 890 km2) and Vatnajo¨kull (ca. 8100 km2)*show a declining specific mass balance from about 0 m yr1 w. eq. on average from 1980 to 1994 to 1 to 1.3 m yr1 w. eq. on average after 1995 (Bjo¨rnsson et al. 2002 /media/ces/Gudmundsson-etal-2011-PR-7282-26519-1-PB.pdf
  • 16. 2013_001_Nawri_et_al

    and a pressure of 1013.25 hPa. In the case of Iceland, the climate deviates significantly from these standard atmospheric conditions. Additionally, terrain elevation varies considerably across the island. Therefore, seasonal and annual differences in air density from the standard value, as well as spatial variability, need to be taken into account. Approximate air density can be calculated by assuming /media/vedurstofan/utgafa/skyrslur/2013/2013_001_Nawri_et_al.pdf
  • 17. vanRoosmalen_etal-2009-WRR_2007WR006760

    and Irrigationa Scenario Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Current 101 85 59 13 6 4 1 6 39 79 84 97 A2 145 132 73 10 10 7 6 8 4 75 92 123 B2 137 119 75 16 6 6 6 5 21 74 110 141 aValues are in millimeters. 10 of 18 W00A15 VAN ROOSMALEN ET AL.: CLIMATE AND LAND USE CHANGE W00A15 time and larger area where groundwater levels rise above the drain levels. Table 6 shows the mean discharges /media/loftslag/vanRoosmalen_etal-2009-WRR_2007WR006760.pdf
  • 18. Adalgeirsdottir-etal-tc-5-961-2011

    Korona et al., 2009) and 2010 (airborne LiDAR in autumn). The Cryosphere, 5, 961975, 2011 www.the-cryosphere.net/5/961/2011/ G. Aðalgeirsdóttir et al.: 20th and 21st century evolution of Hoffellsjökull glacier 963 Fig. 2. (A) Measured bedrock topography of Hoffellsjökull (2001). Blue colours indicate elevation below sea level. (B–E) Surface to- pography at different times, showing retreat /media/ces/Adalgeirsdottir-etal-tc-5-961-2011.pdf
  • 19. 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
  • 20. 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

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