Holocene lavas in Bárðardalur, NE-Iceland La Jolla value of 143Nd/144Nd = 0.511858 (Weis et al., 2005 and references therein) after correction for Sm and Ce interference. Following correction for Lu and Yb interference on 176Hf, measured 176Hf/177Hf were normalized to a JMC-475 value of 176Hf/177Hf of 0.282160 (e.g., Weis et al., 2005). Instrumental mass fractionation for Pb isotopes were corrected us- ing a 205Ti/203Ti spike, assuming an exponential law and the constant ratio of 205Ti/203Ti = 2.3889 (White et al., 2000; Baker et al., 2004). All Pb-isotopic ra- tios were normalized to the SRM981 values of Baker et al. (2004): 206Pb/204Pb = 16.9416, 207Pb/204Pb = 15.4998, and 208Pb/204Pb = 36.7249. Values obtained for both internal and external standards during the course of this study are given in Table 2. Notably, multiple measurements (n = 3 to 5) of the interna- tional rock standard JB-3 are in good agreement with published values (e.g., Fourny et al., 2016). RESULTS Whole Rock Chemistry Bárðarbunga and eruptive units north of Vatnajökull Major, minor and trace element compositions of whole rock samples from the Bárðarbunga basement, Dyngjuháls, Urðarháls, Gígöldur and Hrímöldur were compared to published data from Bárðarbunga and the NRZ (Jakobsson, 1979; Nicholson et al., 1991; Stracke et al., 2003; Halldórsson et al., 2008; Óla- dóttir, 2009; Hartley, 2012; Manning and Thirlwall, 2014; Halldórsson, unpublished). Some of the vol- canic units north of Vatnajökull show large variabil- ity in representative major, minor and trace elements, such as K2O vs. MgO and Zr vs. Y (e.g., Bárðarbunga basement rocks and Gígöldur crater row) (Figures 4a and c). However, majority of the units sampled near the Bárðarbunga central volcano range between 5.28– 8.58 wt% in MgO and 0.08–0.19 wt% in K2O, simi- lar to reported Bárðarbunga-Veiðivötn basalts (Jakob- sson, 1979; Halldórsson et al., 2008; Óladóttir, 2009; Manning and Thirlwall, 2014). The samples collected from the Holocene lava flows at Dyngjuháls overlap in composition with the Bárðarbunga basement rocks. Interestingly, five Dyngjuháls samples are generally more evolved than the others, having elevated K2O, Zr and Y con- tents (Figures 4a and c). We also note that sam- ples from Urðarháls and a single sample available from Hrímalda fall within the main major- and trace- element chemical range of Bárðarbunga and Dyngju- háls. However, two of the Urðarháls samples have >9 wt% MgO. Urðarháls is the only sampled eruptive unit of pre-Holocene age. The Bárðardalur region Major, minor and trace element compositions of whole rock and groundmass samples from the Bárð- ardalur region, were compared to published data from Bárðarbunga and the NRZ (Figures 4b and d). We note the primitive nature of the lava flows, with the groundmass analyses of Kinnarhraun lava display- ing K2O contents of 0.08–0.09 wt% and MgO con- tent around 8.5 wt%. It is also noteworthy that four groundmass samples collected from the Bárðardals- hraun lava (B15–12, B15–13, B15–14, and B15–15) are more evolved than other Bárðardalshraun lava samples, with MgO < 8 wt% and K2O content > 0.1 wt%. A single whole rock sample from the Kvía- hraun lava has a similar MgO value as the more evolved Bárðardalshraun samples. On the other hand, the whole rock samples from the Frambruni and Út- bruni lavas are among the most evolved rocks col- lected from the Bárðardalur valley, both having higher K2O as well as elevated Zr and Y values, but lower MgO than other whole rock samples. A difference in the chemical characteristics of groundmass and whole rock samples from the Kinnarhraun and Bárðardals- hraun lavas is evident in Figures 4b and d, where the whole rock analyses clearly have lower MgO, Zr and Y values compared to the groundmass samples. Lower values of the whole rock samples compared to groundmass samples are due to plagioclase accu- mulation, a characteristic feature of these lava units. As the Kinnarhraun and Bárðardalshraun lavas con- tain variable amounts of plagioclase macrocrysts, we adopt groundmass analyses in further chemical com- parison instead of whole rock analyses. This approach will narrow the compositional range of these lavas in most chemical plots, representing a better candi- date for the composition of the erupted melt, facil- itating the use of these analyses as tools to assess their source provenance. JÖKULL No. 67, 2017 25

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