of Icelandic glaciers 1992–1997). Rep.
OS-98082 (in Icelandic), National Energy Authority, Reykjavík.
Sigurðsson, O., Thorsteinsson Th., Ágústsson S. M. and Einarsson B. 2004.
Afkoma Hofsjökuls 1997–2004. (Mass balance of Hofsjökull 1997–2004.) Rep.
OS-2004/029, National Energy Authority, Reykjavík.
Uppala, S.M., and 45 co-authors 2005. The ERA-40 re-analysis. Q. J. R. Mete-
orol. Soc., 131, 2961
/media/ces/Paper-Olafur-Rognvaldsson_91.pdf
hydrological model. J. Hydrol., 267, 40–52.
Jasper, K., and Kaufmann P. 2003. Coupled runoff simulations as validation
tools for atmospheric models at the regional scale. Q. J. R. Meteorol. Soc., 129,
673–692.
Jóhannesson, T., Aðalgeirsdóttir G., Björnsson H., Crochette P., Elíasson E.
B., Guðmundsson S., Jónsdóttir J. F., Ólafsson H., Pálsson F., Rögnvaldsson
Ó., Sigurðsson O., Snorrason Á
/media/ces/Paper-Olafur-Rognvaldsson_92.pdf
properly even if the
sample size is increased and systematic biases may be expected.
2.2.3 Predictors
Mean sea level pressure (MSLP), geopotential height (Z), specific humidity (q) and tempera-
ture (T) at different pressure levels are considered in this study to describe the meteorological
situations at the synoptic scale and to identify weather analogues. The MSLP and geopotential
height (Z) describe
/media/vedurstofan/utgafa/skyrslur/2014/VI_2014_006.pdf
water.
Since, in this study, the focus is on large-scale storm systems, persisting for at least one day,
variability on shorter time-scales (mainly the diurnal cycle and atmospheric tides) is eliminated
by calculating averages from the four 6-hourly reanalysis fields of each day (6-hourly precip-
8
Figure 1. Top: Average fields of 500 hPa geopotential height in winter (DJF 1989-90)
and summer (JJA
/media/vedurstofan/utgafa/skyrslur/2015/VI_2015_005.pdf
farvegarins undir jöklinum út frá rúmmáli vatns
sem þar hefur safnast fyrir benda til þess að viðnám gegn vatnsrennsli við jökul-
botn minnki eftir því sem líður á hlaupið. Undir lok hlaupsins runnu á bilinu 80–
90 m3 s 1 um farveg sem var einungis einn þriðji hluti af rúmmáli farvegar sem flutti
svipað vatnsmagn á fyrsta eða öðrum degi eftir að hlaupið hófst við jökuljaðar. Þessi
niðurstaða er
/media/vedurstofan/utgafa/skyrslur/2009/VI_2009_006_tt.pdf
: 3601/B2007.EEA53004 and 3601/RO/CLC/
B2007.EEA52971, Landmælingar Íslands, Reykjavik, Iceland.
Bechtold, P., Köhler, M., Jung, T., Doblas-Reyes, F., Leutbecher, M., Rodwell, M. J., Vitart, F.,
and Balsamo, G. (2008). Advances in simulating atmospheric variability with the ECMWF
model: from synoptic to decadal time-scales. Q. J. R. Meterol. Soc., 134:1337–1351.
Brousseau, P., Berre, L., Bouttier
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/media/loftslag/Outline_for_the_case_Road_maintenance_in_a_changing_climate.pdf
horizontal displacement of the most active part of Þófi since the start of
the measurements is mostly in the range 10–35 cm (maximum 69 cm), whereas the movement
in Neðri-Botnar is slower, with the more active points having total displacement mostly in the
range 5–10 cm (maximum 46 cm). The maximum measured velocity of the horizontal movement
in the Þófi area was 92 cm/a over a two-month period in late
/media/vedurstofan-utgafa-2016/VI_2016_006_rs.pdf
contours). Bottom panel: manned and automated surface
observations over Iceland.
13
Figure 4. Hourly rainfall during 3 September 2012, based on HARMONIE model simula-
tions. Times are in UTC (local time).
14
Figure 5. Distribution of low- (red crosses), medium- (green vertical lines), and high-
level (blue horizontal lines) cloud cover of at least 90%, based on HARMONIE model
simulations. Terrain
/media/vedurstofan/utgafa/skyrslur/2015/VI_2015_006.pdf
approximately centred around Iceland: the outer domain with
43 42 grid points spaced at 27 km (1134 1107 km), the intermediate domain with 95 90 grid
points spaced at 9 km, and the inner domain with 196 148 grid points spaced at 3 km. The
northwest corner of the outer domain covers a part of the southeast coastal region of Greenland.
Otherwise, the only landmass included in the model domain
/media/vedurstofan/utgafa/skyrslur/2013/2013_001_Nawri_et_al.pdf