The Kerlingar fault, Northeast Iceland Kerlingar fault. That is unlikely since the easternmost visible part of the Húsavík fault is located 65 km west of the Kerlingar fault. Secondly, the change in orien- tation of fractures in the area should happen abruptly where the fractures and the Húsavík transform fault meet. That is not the case in the area near the Kerl- ingar fault. There, the change of orientation is grad- ual along the border of the rift zone, suggesting even more regional-scale processes. In the third point, it is suggested that the Kerling- ar fault was formed (or reactivated) due to a landrise during the last deglaciation. This can occur as the hot- ter and less viscous NVZ should react differently to unloading due to deglaciation than the colder, thicker and more viscous EFB block. The reaction to unloading is both elastic and vis- cous, partly instantaneous and partly extending over a period of time. Physical properties, i.e. elastic con- stants, viscosity and density, may differ between the NVZ and the EFB, increasing differential stress and inducing faulting between the NVZ and the EFB. a) Effective Young’s modulus Sudden pressure change at the surface leads to instan- taneous elastic reaction of the crust which depends on the effective Young’s modulus, which again is in- versely dependent on crustal thickness. The elastic rebound of the crust happens relatively fast during deglaciation. Variation in Young’s modulus should lead to higher uplift of the EFB than the NVZ (on the order of few tens of centimeters). If this effect was the only effect to cause the formation of the Kerlingar fault, the fault should therefore have a throw towards the west and not towards the east as observed. There- fore, this effect cannot be the only cause of formation of the Kerlingar fault. b) Effective viscosity Lower viscosity material responds more rapidly to de- loading than higher viscosity material with a linear relation between crustal relaxation time and viscosity (e.g. Cathles 1975). Assuming that the lower crustal and uppermost mantle viscosity beneath the volcanic zones of Iceland is lower than beneath older, Ter- tiary areas, the NVZ crust should rebound faster than the EFB during deglaciations. As variable response rates may generate differential stress field across the NVZ-EFB boundary during deglaciations, the Kerl- ingar fault may thus be a remnant of faster rebound of the NVZ crust than the thicker, more viscous EFB crust. Viscous crustal relaxation occurs more slowly and remains over a longer time period than the elastic rebound of the crust. As an example, a region with lower crustal viscosity of 1.5×1019 Pa s, has a relax- ation time of 1000 years (Sigmundsson 2006), while the relaxation time is only 500 years if the viscosity is lowered to 0.75×1019 Pa s. Therefore, a slight differ- ence in the viscosity can cause significantly different relaxation times. c) Density difference – buoyancy effects As the uppermost mantle below the NVZ has a lower density (3170 kg/m3) than beneath the EFB (3240 kg/m3) (Staples et al. 1997), the isostatic uplift of the NVZ during deglaciations should be higher than the uplift of the EFB. Using these mantle densities, an ice density of 920 kg/m3, a 1500 m thick glacier and a simple isostatic uplift equation; u= hice × ρice/ρmantle the uplift of the NVZ is close to 435 m and the uplift of the EFB 426 m, which implies a 9 m excess uplift of the NVZ with respect to the EFB. In addition, flexure at the rift zone margin can cause a different stress field there than in the cen- ter (i.e. Clifton and Kattenhorn 2006). However, marginal flexure should generate faults with a throw down to the west in this area. Therefore, that process cannot explain the existence of the Kerlingar fault, which has a throw down to the east. A differential stress field, produced at the bound- ary between the NVZ and the EFB during deglacia- tions (or glaciations), could explain why the Kerling- ar fault is located at the boundary of the NVZ and the EFB, and why it is parallel to the boundary and not parallel to the fissure swarms in the central NVZ. The differential stress field could form faults in two dif- ferent ways: either directly, without the involvement of magma, or indirectly, by producing a stress field which governs the orientation of dike propagations in the area during deglaciations. Therefore, dike intru- sions could play a part in the scenario, even though JÖKULL No. 60 113

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