Discrete
numerical
Categorical Narrative
Constant in space and time A1 A2 A3
4Varies in time, not in space B1 B2B3
Varies in space, not in time C1 C2 C3
It is noticed that the matrix is in reality three-dimensional
(source, type, nature). Thus, the categories type and nature
are not mutually exclusive, and it may be argued that the ma-
trix should be modified in such a way that the two uncer
/media/loftslag/Refsgaard_etal-2007-Uncertainty-EMS.pdf
and Irrigation
Current climate 560 23 264 243 10 18
A2 scenario + 74 (13%) 0 + 50 (19%) 0 0 + 16 (89%)
B2 scenario + 118 (21%) +1 (4%) + 84 (32%) + 20 (8%) 0 + 9 (50%)
aWater balance values are in millimeters. Relative changes are in parentheses.
Table 4. Spatially Averaged, Mean Monthly Recharge for the
Current Climate and the A2 and B2 Scenarios for the Simulation
Without Abstractions
/media/loftslag/vanRoosmalen_etal-2009-WRR_2007WR006760.pdf
......................... 17
8 Monthly averages of SURFEX or projected 2-m air temperature ...................... 18
9 Local correction factors for 10-m wind speed ............................................... 19
10 Interpolated correction factors for 10-m wind speed ...................................... 20
11 Monthly averages of original or corrected temperature and wind speed .............. 21
12
/media/vedurstofan/utgafa/skyrslur/2014/VI_2014_005.pdf
Journal of Environmental Management 88
Heid
, Øste
d
e
A broad range of tools are available for integrated water resource management (IWRM). In the EU research project NeWater, a
Human dependence on water leaves us vulnerable to
climate change, flood and drought hazards, and poverty
dynamic element of vulnerable groups and their relation-
ship to water resources, and to represent the decisions
/media/loftslag/Henriksen_Barlebo-2008-AWM_BBN-Journ_Env_Management.pdf
) Finland the spring flood peaks are
currently by far the largest floods and as they mostly decreased
with climate change the magnitude of the annual 2 and 100-year
floods decreased. In the north (Fig. 8a) some scenarios still pro-
duced large spring floods in 2070–2099. In southern Finland (in
the coastal rivers Fig. 8e and in the lake area Fig. 8d) large floods
occurred not only in spring but also
/media/ces/Journal_of_Hydrology_Veijalainen_etal.pdf
(Quante and Colijn, 2016). Work on risk analysis and adaptation is in different
stages in the countries of the world.
Coastal floods have caused problems in Iceland in the past (Jóhannsdóttir, 2017) and are likely to do
so in the future as well. Large coastal floods can be expected in Iceland every 10 - 20 years and the
probability of such events can rise with climate change (Almannavarnir, 2011
/media/vedurstofan-utgafa-2020/VI_2020_005.pdf
Av. Ed.
Belin, 31400 Toulouse, France
Received: 21 March 2011 – Published in The Cryosphere Discuss.: 6 April 2011
Revised: 5 October 2011 – Accepted: 20 October 2011 – Published: 2 November 2011
Abstract. The Little Ice Age maximum extent of glaciers in
Iceland was reached about 1890 AD and most glaciers in the
country have retreated during the 20th century. A model for
the surface mass balance
/media/ces/Adalgeirsdottir-etal-tc-5-961-2011.pdf
(alb: AWS)
MODELLING LONG-TERM SUMMER AND WINTER BALANCES
? The authors 2009
Journal compilation ? 2009 Swedish Society for Anthropology and Geography 241
ed temperatures relative to –20°C to account for de-cay of snow albedo at temperatures below the melt-ing point, following a study by Winther (1993). Wetested both approaches, and chose to use –5°C asthe minimum for the accumulated temperature
/media/ces/GA_2009_91A_4_Andreassen.pdf
was therefore formed
by ice lifting and deformation induced by subglacial water pressures higher than ice
overburden pressure.
The discharge data and the derived size of the subglacial flood path, as indicated
by the volume of water stored subglacially, indicates a development towards more
efficient subglacial flow over the course of the jökulhlaup. Thus, a discharge in the
iii
range 80–90 m3 s 1
/media/vedurstofan/utgafa/skyrslur/2009/VI_2009_006_tt.pdf