Sigurjón Jónsson tively creeping show that this technique can be useful in monitoring unstable slopes at many locations and in detecting sites where slope creep is active. In this study I concentrated on ERS-1 and ERS- 2 data from 1993–1999, which all are from a sin- gle frame on descending track 424, and on ascending and descending Envisat data from 2004–2005. More ERS data from track 424 exist that could be used for a more complete InSAR analysis for the time period 1992–1999 and some of the data from after 2001 may also prove to be usable. Data from descending tracks 195 and 152 may also provide additional information. Furthermore, data of this area from other satellites exist, mainly from Radarsat-1, JERS-1, and ALOS, but the archives of data from these satellites were not investigated. The Canadian Radarsat-1 satellite was launched in 1995 and is still in orbit. It operates on a similar wavelength as the European ERS and En- visat satellites and does probably not provide much extra information about the slope deformation during time periods when good ERS and Envisat data exist. However, there may be useful data from 2000–2004 in the Radarsat-1 archives and there may exist more ascending data than in the ERS/Envisat archives. The Japanese JERS-1 satellite was in orbit during 1992– 1998 and operated on L-band wavelength of 23.5 cm, which is much longer than the C-band wavelength (5.6 cm) used by the other satellites. The advantage of this longer wavelength is that temporal decorrela- tion due to surface changes and snow is less promi- nent, so longer-term interferograms using data from this satellite, i.e. spanning several years, would likely prove to be useful. However, JERS-1 radar data of Iceland have never been actively used for interferom- etry, despite undoubtedly rich data archives. The results from Seyðisfjörður and Vopnafjörður show that movement of unstable slopes in eastern Ice- land is episodic, with periods where they do not move at all, while during other periods they may move by many cm. This episodic behavior demonstrates the importance of continuous monitoring of Icelandic slopes, as slow-moving sites may suddenly accelerate or dormant deposits may be reactivated. Such mon- itoring is possible to certain extent with the current radar satellites such as Envisat, i.e. in a similar way as was done within this project using 2004–2005 En- visat data. However, it is important to realize that data above many regions are not routinely acquired. CONCLUSIONS The coherence of C-band radar interferometry is generally good enough for single- and multi-month observations of slope movement in East Iceland. Inter-annual and multi-year observations can also pro- vide useful information on larger deposits, but not on the smaller sites as some filtering is generally re- quired, which prevents small-scale analysis. The main InSAR measurement problems in East Iceland are first, the lack of a digital elevation model of adequate quality, which prevents analysis of long-baseline in- terferograms, and second, the frequent high-elevation snow cover, which often limits the use of spring and autumn images. Deformation was detected in Þófi near Seyðis- fjörður in InSAR data from 2 years before 2000, when surface cracks were discovered in the field. Interfer- ograms spanning several months in summers of 1998 and 1999 show 2–3 cm of LOS displacement that may represent surface parallel velocities of 7–10 cm/year. This rate is lower than the maximum observed GPS velocities during 2001–2002 (up to 33 cm/year), but no suitable InSAR data exist from that time period to compare with the GPS data. No deformation was detected in InSAR images 1995–1997 or 2004–2005 at the Þófi site, indicating that the deposits creep episodically. More than 10 locations of previously unknown slope creep were discovered in East Iceland in the pro- cessed interferograms. In some cases the locations of observed creep correspond to deposits that have been geomorphologically documented. The most promi- nent moving deposits were found in Vopnafjörður and in Loðmundarfjörður. The Vopnafjörður creep shows variations in both displacement rate and areal extent during the observation period, which further demon- strates the episodic behavior of creeping slopes in East Iceland. 100 JÖKULL No. 59

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