Geirsson et al. matic intrusion (Jakobsdóttir et al., 2008; White et al., 2009). Two CGPS stations (SAUD and BRUJ) showed clear signs of the intrusion (Figure 3). The lack of vertical motion detected at the stations, relative to the horizontal velocity change of about 30 mm/yr, was interpreted as a dipping dike of a volume of 0.05 km3 was intruding into the crust (Jakobsdóttir et al., 2008). This model was further supported by episodic GPS measurements and modeling of InSAR observa- tions (Hooper et al., 2009). The deformation ceased in April 2008 following a culmination and a change in character of the seismic activity (Geirsson et al., 2009). The episode has been interpreted as a magma in- trusion into the lower parts of the crust (12–20 km depth), and the earthquakes are thought to be caused by brittle fracturing of the host rock where magma is intruding. This episode provided the first real test of the ability of using data from the CGPS network to follow a magma intrusion. The CGPS network proved very valuable for assessing the state of the in- trusive episode along with seismic and other deforma- tion data. Load induced deformation Glacier retreat Warming climate is causing the glaciers in Iceland to melt by thinning of the ice caps and retreat of the edges (Björnsson and Pálsson, 2008). The melting re- duces the load on the Earth’s crust, resulting in crustal uplift around and under the glaciers. This uplift has been captured by the CGPS network (Figure 4), and importantly also by two GPS campaigns in 1993 and 2004 that covered the whole of Iceland (Árnadóttir et al., 2009). The observations show that a broad area in central Iceland is being uplifted by more than 1–2 cm/yr. This result, along with models of the history of the ice load deduced from glaciological observations, has been used to infer crustal structure and viscoelas- tic properties of the crust (Árnadóttir et al., 2009). Interestingly, the present uplift rates observed by the CGPS network deviate somewhat from the 1993 to 2004 episodic campaigns, with higher present rates of uplift, which may reflect increased melting rates of the ice-caps since mid-1990. In addition to the high uplift rates, annual cyclic variations in the CGPS site elevation are also observed (Geirsson et al., 2006), co- inciding with annual snow accumulation and melting of the ice caps (Grapenthin et al., 2006). Grapenthin et al. (2006) used these observations to infer the elas- tic properties of the crust, since viscoelastic response can be ignored for annual frequencies. The Hálslón water reservoir In September 2006, a new 25 km long and 2 km wide lake, with a maximum depth of nearly 200 me- ters, was formed north of the Vatnajökull ice-cap for a hydro-electric power plant (Figure 3). The Icelandic National Power Company had a network of seismic stations and three CGPS stations installed by IMO in the area to follow possible deformation and seismicity caused by the formation of the lake. The CGPS defor- mation monitoring was augmented by episodic GPS measurements in the area (Ófeigsson, 2008). Three of the episodic sites were upgraded to continuous sites, coming into full operation in 2008. The CGPS sites show a maximum of 15 mm observed subsidence due to the initial filling of the lake. The observed deforma- tion during the initial filling of the reservoir seems to rather indicate outward movement (Ófeigsson, 2008). The reservoir is subject to large annual variations in lake level, around 50 m in a normal year, with a high- stand in September. Seasonal variations are observed in the CGPS time series, but they are subtle and prob- ably partly counter-balanced by the opposite phase in load changes at Vatnajökull. Other transient deformation Krísuvík uplift-subsidence episode A rapid increase in seismic activity accompanied with a significant surface uplift in the Krísuvík region (Fig- ure 1) was detected in 2009. This is the first time such activity has been documented on the Reykjanes Penin- sula. Continuous GPS measurements started in Krísu- vík in February 2007 when the station KRIV was in- stalled. A velocity anomaly is apparent in the time series from KRIV since late 2008 or early 2009 (Fig- ure 8). The station has experienced both increased southward motion and uplift followed by a period of reversed motion. During the period of uplift, seismic 16 JÖKULL No. 60

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