Magnússon et al. riod 1755–2016 was close to the one required to main- tain the present elevation at these ice divide, while it was above this value in the period 1755–1918, result- ing in net elevation gain and below it in 1918–2016 resulting in net lowering. The good agreement between the depth of the 1755 layer from the static modelled velocity field and the depth of the deep tephra layer, which independent of the model result is quite likely to be formed by the 1755 eruption of Katla, raises the question: How old is the ice below the tephra layer, which we mark as 1755? With the same method, we would approximate the elevation of ice made from snow falling on the glacier in 1200 AD to be somewhat less than 100 m from the glacier bed. However, our model does not include basal melting, so older ice will not be consid- ered. Given the good agreement between the mod- elled and observed depth of tephra layers, as well as recent work estimating basal melting of Icelandic glacier (Jóhannesson et al., 2020) we consider it un- likely that the annual basal melt rate beneath these ice divides (Figure 8b and 8d) is higher than 0.1 m a−1 (90 m of ice since 1200 AD); at present no clear caul- drons formed by subglacial geothermal activity are at this location. Our age estimate should, however, be considered with caution due to the assumption of fixed glacier surface; the glacier is expected to have been substantially thinner for a good part of the pe- riod since 1200 AD (e.g. Björnsson, 2017). With that in mind we still consider it likely that the age of the ice near the bed at the ice divides is 600–800 years or even higher. Applying time-dependent models for Mýrdalsjökull with varying geometry and mass bal- ance should provide further constraints on this. Mod- els aimed to simulate the development of Mýrdalsjök- ull and its mass balance in the past centuries should ideally use the constraint given by the depth, at the ice divides, down to the 1918 tephra layer as well what we identify as the 1755 tephra layer. CONCLUSIONS The comprehensive RES-surveys presented here have resulted in a revised bedrock DEM of the Katla caldera, which is unprecedented in terms of details for an ice covered volcano, particularly in areas where dense survey profiles allowed for 3D migration of the RES-data. It has also resulted in unique maps, show- ing the topography of two tephra layers, buried in ice, that have been shaped by subglacial geothermal activ- ity and high surface mass balance rates, since 1918 for the younger tephra layer and since 1755 for the older layer, according to our dating. In addition to pre- senting these new results and describing in detail how they were obtained, we have listed and discussed var- ious interesting features revealed in the bedrock and tephra layer topography. Further studies are required in many cases to understand some of these features, including various topographic structures beneath the glacier, or whether some observed shapes in the tephra layers are caused by geothermal activity, ice dynam- ics or spatially variable surface mass balance. The presented data sets will serve as vital input in various new studies, aiming to better understand subglacial geothermal activity, ice cauldrons, ice dynamics, sub- glacial hydrology and jökulhlaups, as well as the link between all these processes. Such studies have al- ready started (e.g. Jarosch et al., 2020). Furthermore, the detailed bedrock DEM and the topographic map- ping of the dated isochrones within the glacier may serve as key data for studying the development and mass balance of Mýrdalsjökull in the past centuries. Addendum: The bedrock topography at the esti- mated location of the 1918 eruption Results from a recent study (Gudmundsson et al., 2021) have led to relocation of the 1918 eruption to a site outside the span of the RES-data acquired in 2012–2019. It was therefore decided to carry out more RES-surveying in this part of the Katla caldera in May 2021. This included both a ∼1 km2 area, surveyed with dense RES-profiles allowing for 3D migration, as well as 15 km of 2D migrated profiles (Figure 12a). The survey was carried out after the acceptance of this paper for publication in Jökull but despite this the new RES-data has been incorporated into the text, figures and tables of this paper, without changing any of the main findings presented above. The bedrock map of the area specifically mea- sured in 2021 (Figure 12b) is also shown as 3D rep- resentation in Figure 10b and on the cover image of 64 JÖKULL No. 71, 2021

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