Geirsson et al. Hengill transient deformation The 1994 to 1998 Hengill intrusion and seismic ac- tivity (Feigl et al., 2000) had an important impact on starting the network of CGPS measurements for haz- ards monitoring in Iceland. The stations closest to the 1994–1998 magma intrusion, HVER and OLKE (Figure 8), were installed in April and May 1999. By then the activity had already ceased, and the sites show no significant signals of the 1994 to 1998 intru- sion. However, the sites in the area have shown sig- nificant temporal variation in site velocities (Figure 8) with gradually increasing velocities towards north and west and subsidence at increasing rates. In particu- lar, OLKE subsided and moved more rapidly towards west during 2006–2010 than before. A new geother- mal power plant started operating in the Hengill area in 2006, and the production capability of an older geothermal power plant drawing fluids from the north- ern part of the area was increased substantially in 2008. It is tempting to suggest that the increase in geothermal fluid withdrawal is causing the changes in the site motions in the Hengill area, however, more detailed research is required because a wealth of other geodetic data better suited for spatial constraints of the deformation source exists for the area. DISCUSSION Since the first CGPS station was installed in Reykja- vík in 1995, the signals captured by the growing CGPS network have been of a great importance to the scientific community and civil defense in Iceland. Data from the network have also been used as a ref- erence for numerous precision mapping projects. The processes causing surface deformation in Iceland are diverse, covering plate motion, earthquakes, erup- tions, magma movements, glacial rebound, and pres- sure changes in geothermal systems. CGPS is one of the available tools to study these processes. The inte- gration of CGPS data with other geodetic techniques (e.g. episodic and semi-continuous GPS, InSAR, tilt, and leveling), seismic, and other data of relevance has proven well, emphasizing the importance of interdis- ciplinary cooperation. We have yet to capture a plate boundary rifting event by the CGPS network, which seem to occur ev- ery few hundred years on the plate boundary. The last rifting episode in Iceland occurred in the Krafla volcanic system in 1975–1984 (e.g. Björnsson, 1985). The latest rifting episode in the Eastern Volcanic Zone occurred 1862–1864 in the Bárðarbunga volcanic sys- tem (Thorarinsson and Sigvaldason, 1972) but a major event took place in 1783–1785, when the Lakagígar crater row formed and around 27 km3 were erupted (Thordarson and Larsen, 2007). Although much can be learned from the ongoing Afar rifting episode (e.g. Ebinger et al., 2010), there are questions specific to Iceland that need to be addressed by direct observa- tions, such as improved understanding of the magma plumbing systems, the propagating EVZ (LaFemina et al., 2005), and precursors of rifting episodes. The south Iceland seismic crisis in 2000 and 2008 demonstrated the importance of the CGPS network and applications of high-rate data sampling. Since only a part of the accumulated energy has been re- leased in the SISZ, continuation of the sequence might be expected. The Húsavík-Flatey fault in northern Ice- land had its last large earthquake in 1872 and may be due for another event, although results from the CGPS network indicate that the Grímsey oblique rift is presently taking up a majority of the deformation in the Tjörnes fracture zone. Some of the most active volcanoes in Iceland are now being monitored with continuous GPS. However, most of the EVZ, where the volcanic production in Iceland is greatest, is poorly instrumented. The same holds true for many recently active volcanoes such as Krafla, Askja, and Öræfajökull. The ability of the CGPS technique to track subsurface magma move- ments with time, as best demonstrated by the 2009– 2010 Eyjafjallajökull intrusive and eruptive episodes, has the potential of being pushed further towards real- time. There is a global concern for ongoing climate change, and the retreat of the Icelandic ice-caps cause the observed rapid uplift of the highlands in cen- tral Iceland. The CGPS data have been used to con- strain structural parameters of the Icelandic crust, but they could as well be used as an indirect measure of 18 JÖKULL No. 60

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