The 2011 unrest at Katla volcano cic eruptions are not reported since then, possibly in- dicating a substantial change in the plumbing system caused by the Eldgjá eruption (Óladóttir et al., 2008). In historical times, Katla has been the most pro- ductive volcanic system in Iceland in terms of magma volume erupted (Thordarson and Larsen, 2006). It has generated observable subaerial eruptions fairly regu- larly at a rate of 1–3 eruptions per century, with re- pose periods ranging between 13 and 98 years, and averaging 47 years since AD 1500 (Larsen, 2000). Recent activity The last eruption to break the ice surface was an ex- plosive basaltic eruption in 1918 that produced a ∼14 km high eruptive plume and tephra fallout (0.7 km3), accompanied by a massive jökulhlaup that deposited a large volume of juvenile eruptive materials. The erup- tion site was located near the south rim of the caldera beneath ∼400 m of ice (Eggertsson, 1919; Sveinsson, 1919; Larsen, 2000). Periods of elevated seismicity, not associated with eruptive activity, occurred at Katla in 1967 and 1976– 77 inside the caldera and at Goðabunga (Einarsson, 1991). Two minor subglacial eruptions, but with no subaerial tephra emission, may have occurred in June 1955 and July 1999. The 1955 event took place near the eastern rim of the caldera (Figure 2) where two shallow ice cauldrons formed and a small jökulhlaup drained from south-east Mýrdalsjökull (Thorarinsson, 1975). In 1999, a new ice cauldron formed on the glacier (Guðmundsson et al., 2007) and a jökulhlaup was released from Sólheimajökull (Sigurðsson et al., 2000; Roberts et al., 2003), associated with earth- quakes and bursts of tremor. From 1999 to 2004, GPS measurements on nunataks exposed along the caldera rim revealed steady uplift of the volcano, interpreted to result from 0.01 km3 of magma accumulation (Sturkell et al., 2006, 2008). Consequently, Guðmundsson et al. (2007) showed that increased geothermal heat output occurred in 2001–2003 based on the evolution of ice cauldrons, together with the increased seismicity and ground uplift. However, a recent study by Spaans et al. (2015) reported that the uplift may be due to glacial isostatic adjustment as a consequence of mass loss of Iceland’s ice caps. JULY 2011 UNREST A significant, general increase in seismicity started at Katla in July 2011 and lasted until winter 2011. This followed a period of uplift of most ice cauldrons on Mýrdalsjökull (11–12 m at cauldron 16) between Au- gust 2010 and July 2011, resulting from water accu- mulation under the glacier (Guðmundsson and Sólnes, 2013). The seismicity intensified especially in the south- ern sector of the caldera and culminated with a 23- hour tremor burst on July 8–9th (Sgattoni et al., 2016b, 2017). No signs of eruption breaking the ice were observed, but a ∼18 million m3 jökulhlaup drained from Kötlujökull and some ice cauldrons deepened in the southern and eastern parts of Mýr- dalsjökull (Figure 2). The jökulhlaup swept away the bridge over Múlakvísl river early in the morning of July 9th. This coincided with a clear flood-related tremor phase lasting around 5 hours. Two main tremor sources were identified in the southern and eastern caldera, corresponding to the active cauldrons, and were interpreted to be associated with either geother- mal or magmatic processes (Sgattoni et al., 2017). At the same time, a new earthquake source be- came active on the southern flank near the Gvendarfell ridge, at the edge of the glacier (Figure 2). This seis- micity consists of long-period events with an emer- gent P wave and an unclear S wave, and has a peculiar temporal pattern characterized by regular inter-event times modulated by a seasonal correlation. Due to their temporal pattern and the depth distribution of the hypocentres (Sgattoni et al., 2016a), they are inferred to relate to volcanic rather than glacial processes. The events locate in the shallow subsurface between 0.5 and 0.9 km depth, but the depth is marginally re- solved to differ from zero. The size of the cluster in- ferred from relative location is on the order of 100 me- ters (Sgattoni et al., 2016a). Both magmatic and hy- drothermal processes are considered possible (Sgat- toni et al., 2016a,c). EARTHQUAKE ACTIVITY 1998–2015 Catalogue data from the Icelandic Meteorological Of- fice (IMO) give an overview of the seismic activity at Katla during the period 1998–2015, as a framework JÖKULL No. 69, 2019 57

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