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
Pw at Bulken andRøldal indicated a slightly higher mean bw for theperiod 1923/24–1948/49, 1.3 m w.e., than calculat-ed by the model using a temperature threshold of3°C for Psolid. The bw for the period prior to 1895/96–1922/23 was also 1.3 m w.e. using precipitationdata from Bulken. The reconstructed bw further in-dicated that the high winter balances measured inthe period 1989–1995 with a maximum
/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
on the European level [e.g.
Water Framework Directive (Directive 2000/60/EC),
Common Agricultural Policy, etcetera], except for the
Ukrainian part of the Tisza. However, the Ukraine shows
strong incentives to enter the EU community and thus the
EU acquis communautaire is used as key reference for the
development of its water management principles. It was
nevertheless decided to select two case-studies
/media/loftslag/Huntjens_etal-2010-Climate-change-adaptation-Reg_Env_Change.pdf
respec-
tively. Due to limited data availability, for the SMHI-RCAO run, the 20th Century control period
is restricted to the 20-year period 1971–90, and the second 21st Century reference period is limited
to the years of 2070–80. For the MetNo-HIRHAM runs, no data are available during the second
21st Century reference period.
3 Spatial Variability of Climate Trends
This section discusses
/media/ces/2010_005_.pdf
is on the northern North Atlantic and the Nordic Seas. With the southern
boundary at 47 N, the study domain covers Newfoundland, but excludes various marginal and
inland seas with significant independent storm activity, such as the Mediterranean and Adriatic
Seas, as well as the Black and Caspian Seas. The northern boundary at 80 N takes the domain
up to Fram Strait, including Svalbard, but excluding
/media/vedurstofan/utgafa/skyrslur/2015/VI_2015_005.pdf
and review of some methods for regional flood frequency anal-
ysis. J. Hydrol., 186, 63–84.
GREHYS. (1996b). Inter-comparison of regional flood frequency procedures for Canadian rivers.
J. Hydrol., 186, 85–103.
Grover, P.L., Burn, D.H. & Cunderlik, J.M. (2002). A comparison of index flood estimation
procedures for ungauged catchments. Can. J. Civ. Eng., 29, 734–741.
Hosking, J.R.M. & Wallis, J.R. (1993
/media/vedurstofan/utgafa/skyrslur/2015/VI_2015_009.pdf
;
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/media/loftslag/Hare-2011-ParticipatoryModelling.pdf
Medium C2! C4 0.8
C4! C6
C8! C9
Weak C2! C1 0.7
Medium Strong – 0.6
Medium C3! C4 0.5
C4! C7
C11! C9
C7! C8
C8! C1
C1! C6
C9! C2C9! C6
Weak Strong C7! C1 0.4
C9! C7
Medium C4! C2 0.3
C6! C1
C6! C7
Weak C5! C4 0.2
C7! C6
K. Kok / Global Environmental Change 19 (2009) 122–133126
Author's personal copy
growth is a less important factor, but relative to other
processes is it still a medium important
/media/loftslag/Kok_JGEC658_2009.pdf